Serialization floors and deadline driven control for performance optimization of asymmetric multiprocessor systems

ABSTRACT

Closed loop performance controllers of asymmetric multiprocessor systems may be configured and operated to improve performance and power efficiency of such systems by adjusting control effort parameters that determine the dynamic voltage and frequency state of the processors and coprocessors of the system in response to the workload. One example of such an arrangement includes applying hysteresis to the control effort parameter and/or seeding the control effort parameter so that the processor or coprocessor receives a returning workload in a higher performance state. Another example of such an arrangement includes deadline driven control, in which the control effort parameter for one or more processing agents may be increased in response to deadlines not being met for a workload and/or decreased in response to deadlines being met too far in advance. The performance increase/decrease may be determined by comparison of various performance metrics for each of the processing agents.

BACKGROUND

A multi-core processor may be implemented as a single computingcomponent having two or more independent processing units called“cores.” Cores are units that read and execute program instructions. Thesingle computing component can run multiple instructions on separatecores at the same time, increasing overall speed for tasks amenable toconcurrent computing. The multiple cores may be incorporated onto asingle integrated circuit or may be multiple integrated circuitsintegrated into a single package. Multicore processors may be consideredas belonging to two different categories, symmetric multicore processors(SMP) and asymmetric multicore processors (AMP). An SMP includes two ormore processor cores controlled in a way that treats all processors moreor less equally, reserving none for special purposes. SMPs may have aplurality of cores of a same core type. Conversely, AMPs may have aplurality of cores of different types, architectures,microarchitectures, etc. Each core of an AMP may or may not run anoperating system and/or may be controlled more independently than in thecase of an SMP.

In some embodiments, an AMP can have a first set of “efficiency cores”that may be more efficient than a second set of “performance cores.” Insome cases, the efficiency cores may be designed to minimize energyconsumed per instruction processed. Performance cores may be designed tomaximize a number of instructions processed per unit of time. In someembodiments, other types of processors may be provided, such as graphicsprocessing units (GPUs), which may include multiple GPU cores orexecution units, neural engines optimized for accelerating neuralnetwork operations, and other types of processors or coprocessors suchas an image signal processor, a scaling and rotating engine, etc. Anexemplary embodiment of an AMP embodying multiple cores of multipletypes is the A11 Bionic chip designed by Apple Inc. of Cupertino,Calif., which includes a six-core CPU featuring two performance coresand four efficiency cores, a three core GPU, and a neural engine.

A potential advantage of AMPs is that different components or processingcores can more quickly and/or more efficiently perform certainoperations. In some embodiments, one processor core (e.g., a CPU core)may package instructions and data associated with a particular thread orthread group for another processing component (e.g., a GPU). During thetime that the GPU (for example) is working on the thread or threadgroup, the CPU (for example) may be freed up to perform other tasks(improving processing throughput) or may be transitioned to a lowerpower state (improving power efficiency). It is known in the art toobtain efficiency by reducing the voltage/frequency supplied to aprocessor core, or even to set a core to an idle or “dark” mode in whichthe core is shut down and not processing instructions. However, in somecases a substantial amount of time may be required to bring a core backto a higher performance processing state, which can negatively affectperformance. Thus, it may be desirable to provide alternative powermanagement techniques for asymmetric multi-core processors that canaccount for the relative workloads and timings of the differentprocessing components.

SUMMARY

A method of controlling performance of one or more processors orcoprocessors of an asymmetric multiprocessor system can includeexecuting a thread group on a processor and a coprocessor of theasymmetric multiprocessor system, wherein the thread group has a firstcontrol effort parameter corresponding to the processor and a secondcontrol effort parameter corresponding to the coprocessor. The methodcan further include and at least one of performing a hystereticadjustment of the first control effort parameter to transition theprocessor to a low power state while a workload associated with thethread group is executing on the coprocessor or performing a hystereticadjustment of the second control effort parameter to transition thecoprocessor to a low power state while a workload associated with thethread group is executing on the processor. The hysteretic adjustmentcan include delaying a time between a workload being submitted to thecoprocessor and decreasing the first control effort parameter. Thehysteretic adjustment can alternatively or additionally includedecreasing a rate at which the first control effort parameter decreases.The processor and/or coprocessor may be a central processing unit, agraphics processing unit, a general purpose graphics processing unit, aneural engine, an image signal processor, a scaling and rotating engine,etc. The control effort parameter can affect at least one of anallocated subset of cores or execution units and a dynamic voltage andfrequency state of the processor.

A method of controlling performance of one or more processors orcoprocessors of an asymmetric multiprocessor system can also includeexecuting a thread group on a processor and a coprocessor of theasymmetric multiprocessor system, wherein the thread group has a firstcontrol effort parameter corresponding to the processor and a secondcontrol effort parameter corresponding to the coprocessor, storing avalue of the first control effort parameter when a workload is submittedto the coprocessor, and resetting the first control effort parameter toa value derived from the stored value of the first control effortparameter when a result of the workload is delivered to the processor.Resetting the first control effort parameter to a value derived from thestored value of the first control effort parameter can include resettingthe first control effort parameter to the stored value of the firstcontrol effort parameter. Resetting the first control effort parameterto a value derived from the stored value of the first control effortparameter can also include resetting the first control effort parameterto the stored value of the first control effort parameter times a factorderived from the degree of serialization of the workload. Resetting thefirst control effort parameter to a value derived from the stored valueof the first control effort parameter can also include resetting thefirst control effort parameter to the stored value of the first controleffort parameter times a factor derived from a length of time requiredto execute the workload. Resetting the first control effort parameter toa value derived from the stored value of the first control effortparameter can also include resetting the first control effort parameterto the stored value of the first control effort parameter times a tuningfactor. The tuning factor may be derived from a performance priority ofthe workload, and/or a desired level of power consumption for theworkload. The processor and/or coprocessor may be a central processingunit, a graphics processing unit, a general purpose graphics processingunit, a neural engine, an image signal processor, a scaling and rotatingengine, etc. The control effort parameter affects at least one of anallocated subset of cores or execution units and a dynamic voltage andfrequency state of the processor.

An asymmetric multiprocessor system can include a processor complexcomprising one or more processors, one or more coprocessors, a closedloop performance controller configured to control performance of the oneor more processors and the one or more coprocessors, and an operatingsystem executing on the processor complex. The operating system caninclude an input/output service interactive with the closed loopperformance controller and one or more drivers corresponding to the oneor more coprocessors. The performance controller may be configured tocooperate with the operating system, the processor complex, and the oneor more coprocessors to execute a thread group on a processor and acoprocessor of the asymmetric multiprocessor system, wherein the threadgroup has a first control effort parameter corresponding to theprocessor and a second control effort parameter corresponding to thecoprocessor and at least one of perform a hysteretic adjustment of thefirst control effort parameter to transition the processor to a lowpower state while a workload associated with the thread group isexecuting on the coprocessor, or perform a hysteretic adjustment of thesecond control effort parameter to transition the coprocessor to a lowpower state while a workload associated with the thread group isexecuting on the processor. The hysteretic adjustment can includeintroducing a delay between the time that a workload is submitted to thecoprocessor and the time at which the first control effort parameter isdecreased. The hysteretic adjustment can also include decreasing a rateat which the first control effort parameter decreases. The processorand/or coprocessor may be a central processing unit, a graphicsprocessing unit, a general purpose graphics processing unit, a neuralengine, an image signal processor, and a scaling and rotating engine.The control effort parameter may affect at least one of an allocatedsubset of cores or execution units and a dynamic voltage and frequencystate of the processor.

An asymmetric multiprocessor system can include a processor complexcomprising one or more processors, one or more coprocessors, a closedloop performance controller configured to control performance of the oneor more processors and the one or more coprocessors, and an operatingsystem executing on the processor complex. The operating system caninclude an input/output service interactive with the closed loopperformance controller and one or more drivers corresponding to the oneor more coprocessors. The closed loop performance controller may beconfigured to cooperate with the operating system, the processorcomplex, and the one or more coprocessors to execute a thread group on aprocessor and a coprocessor of the asymmetric multiprocessor system,wherein the thread group has a first control effort parametercorresponding to the processor and a second control effort parametercorresponding to the coprocessor, store a value of the first controleffort parameter when a workload is submitted to the coprocessor, andreset the first control effort parameter to a value derived from thestored value of the first control effort parameter when a result of theworkload is delivered to the processor.

The closed loop performance controller may reset the first controleffort parameter to a value derived from the stored value of the firstcontrol effort parameter by resetting the first control effort parameterto the stored value of the first control effort parameter. The closedloop performance controller may also reset the first control effortparameter to a value derived from the stored value of the first controleffort parameter by resetting the first control effort parameter to thestored value of the first control effort parameter times a factorderived from the degree of serialization of the workload. The closedloop performance controller may also reset the first control effortparameter to a value derived from the stored value of the first controleffort parameter by resetting the first control effort parameter to thestored value of the first control effort parameter times a factorderived from a length of time required to execute the workload. Theclosed loop performance controller may also reset the first controleffort parameter to a value derived from the stored value of the firstcontrol effort parameter by resetting the first control effort parameterto the stored value of the first control effort parameter times a tuningfactor. The tuning factor may be derived from a performance priority ofthe workload and/or a desired level of power consumption for theworkload. The processor and/or coprocessor may be a central processingunit, a graphics processing unit, a general purpose graphics processingunit, a neural engine, an image signal processor, and a scaling androtating engine. The control effort parameter may affect at least one ofan allocated subset of cores or execution units and a dynamic voltageand frequency state of the processor.

A method of controlling performance of a plurality of processing agentsin an asymmetric multiprocessor system can include executing a threadgroup on at least first and second processing agents of the asymmetricmultiprocessor system, the thread group having a completion deadline,determining whether the thread group was completed before the completiondeadline, and responsive to a determination that the thread group wasnot completed before the deadline, increasing the performance of atleast one processing agent based on a comparison of performance metricsfor the at least first and second processing agents. The comparison ofperformance metrics for the at least first and second processing agentscan include a comparison of execution time for the at least first andsecond processing agents. The comparison of performance metrics for theat least first and second processing agents can also include acomparison of critical execution time for the at least first and secondprocessing agents. The comparison of performance metrics for the atleast first and second processing agents can also include a comparisonof power efficiency for the at least first and second processing agents.Power efficiency may be determined by analyzing past power consumptionof the at least first and second processing agents.

Increasing the performance of at least one processing agent based on acomparison of performance metrics for the at least first and secondprocessing agents can include increasing the performance of each of theat least first and second processing agents. Increasing the performanceof each of the at least first and second processing agents can includeincreasing the performance of each of the at least first and secondprocessing agents in proportion to their contribution to a total of thecompared performance metrics. Increasing the performance of at least oneprocessing agent can include increasing the performance of at least oneprocessing agent in discrete steps along a ladder of fixed performancestates.

A method of controlling performance of a plurality of processing agentsin an asymmetric multiprocessor system can further include determiningwhether the thread group was completed too soon before the completiondeadline and, responsive to a determination that the thread group wascompleted too soon before the deadline, decreasing performance of atleast one processing agent based on a comparison of performance metricsfor the at least first and second processing agents. The comparison ofperformance metrics for the at least first and second processing agentscan include a comparison of execution time for the at least first andsecond processing agents. The comparison of performance metrics for theat least first and second processing agents can also include acomparison of critical execution time for the at least first and secondprocessing agents. The comparison of performance metrics for the atleast first and second processing agents can also include a comparisonof power efficiency for the at least first and second processing agents.Power efficiency can be determined by analyzing past power consumptionof the at least first and second processing agents. Decreasing theperformance of at least one processing agent based on a comparison ofperformance metrics for the at least first and second processing agentscan include decreasing the performance of each of the at least first andsecond processing agents. Decreasing the performance of each of the atleast first and second processing agents can also include decreasing theperformance of each of the at least first and second processing agentsin proportion to their contribution to a total of the comparedperformance metrics. Decreasing the performance of at least oneprocessing agent can also include decreasing the performance of at leastone processing agent in discrete steps along a ladder of fixedperformance states.

An asymmetric multiprocessor system can include a processor complexcomprising a plurality of processing agents, a closed loop performancecontroller configured to control performance of the plurality ofprocessing agents, and an operating system executing on the processorcomplex, the operating system comprising an input/output serviceinteractive with the closed loop performance controller. The closed loopperformance controller may be configured to cooperate with the operatingsystem and the plurality of processing agents to execute a thread grouphaving a completion deadline, determine whether the thread group wascompleted before the completion deadline; and responsive to adetermination that the thread group was not completed before thedeadline, increasing the performance of at least one processing agentbased on a comparison of performance metrics for the plurality ofprocessing agents. The comparison of performance metrics for theplurality of processing agents can include a comparison of executiontime for the plurality of processing agents, a comparison of criticalexecution time for the plurality of processing agents, and/or acomparison of power efficiency for the plurality of processing agents.Power efficiency may be determined by analyzing past power consumptionof the plurality of processing agents.

The closed loop performance controller can increase the performance ofat least one processing agent based on a comparison of performancemetrics for the plurality of processing agents by increasing theperformance of each of the plurality of processing agents. The closedloop performance controller can increase the performance of each of theplurality of processing agents by increasing the performance of each ofthe plurality of processing agents in proportion to their contributionto a total of the compared performance metrics. The closed loopperformance controller can increase the performance of at least oneprocessing agent by increasing the performance of at least oneprocessing agent in discrete steps along a ladder of fixed performancestates.

The closed loop performance controller may be further configured tocooperate with the operating system and the plurality of processingagents to determine whether the thread group was completed too soonbefore the completion deadline and, responsive to a determination thatthe thread group was completed too soon before the deadline, decreaseperformance of at least one processing agent based on a comparison ofperformance metrics for the plurality of processing agents. Thecomparison of performance metrics for the plurality of processing agentscan include a comparison of execution time for the plurality ofprocessing agents, a comparison of critical execution time for theplurality of processing agents, and/or a comparison of power efficiencyfor the plurality of processing agents. Power efficiency may bedetermined by analyzing past power consumption of the plurality ofprocessing agents.

The closed loop performance controller may decrease the performance ofat least one processing agent based on a comparison of performancemetrics for the plurality of processing agents by decreasing theperformance of each of the plurality of processing agents. The closedloop performance controller may decrease the performance of each of theplurality of processing agents by decreasing the performance of each ofthe plurality of processing agents in proportion to their contributionto a total of the compared performance metrics. The closed loopperformance controller may decrease the performance of at least oneprocessing agent by decreasing the performance of at least oneprocessing agent in discrete steps along a ladder of fixed performancestates.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a block diagram of a processing system having aplurality of core types each having one or more cores.

FIG. 2 illustrates a block diagram of a closed loop performance control(CLPC) system of a system for controlling performance of threadsbelonging to thread groups on a processor comprising a plurality of coretypes.

FIG. 3 illustrates a system to maintain performance metrics forworkloads spanning multiple agents.

FIG. 4 illustrates a method to offload a workload to a co-processor.

FIG. 5 illustrates a method of tracking performance metrics for anoffloaded workload.

FIG. 6 illustrates an additional method of tracking performance metricsfor an offloaded workload.

FIG. 7 illustrates a method of tracking performance metrics for anoffloaded workload of a work interval object.

FIG. 8 illustrates a CPU/GPU workload.

FIG. 9 illustrates a CPU/GPU workload with unwind hysteresis for CPU andGPU control effort.

FIG. 10 illustrates a flow chart of a processor/coprocessor controleffort management technique implementing increased hysteresis.

FIG. 11 illustrates an exemplary CPU/GPU workload with control effortseeding.

FIG. 12 illustrates a flow chart of a processor/coprocessor controleffort management technique implementing control effort seeding.

FIGS. 13A-13C illustrate three workloads exhibiting different degrees ofserialization.

FIG. 14 illustrates a flow chart for a method 1400 of determining acontrol effort floor.

FIG. 15A illustrates an exemplary workload for a multiprocessor systemlike that in FIG. 3 having a processor complex and first and secondcoprocessors.

FIG. 15B illustrates an exemplary workload for a multiprocessor systemdepicting critical time for various processing elements.

FIGS. 16A-16B illustrate methods for adjusting the performance ofvarious agents in a multiprocessor system based on utilization.

FIGS. 17A-17B illustrate methods for adjusting the performance ofvarious agents in a multiprocessor system based on critical utilization.

FIGS. 18A-18B illustrate methods for adjusting the performance ofvarious agents in a multiprocessor system based on efficiency.

FIG. 19 illustrates an example scalability model based control system.

DETAILED DESCRIPTION

In the following detailed description, reference is made to theaccompanying drawings in which like references indicate similarelements, and manners in which specific embodiments may be practiced areshown by way of illustration. These embodiments are described insufficient detail to enable those skilled in the art to practice theinvention, and it is to be understood that other embodiments may beutilized, and that logical, mechanical, electrical, functional, andother changes may be made without departing from the scope of thepresent disclosure. The following detailed description is, therefore,not to be taken in a limiting sense, and the scope of the presentinvention is defined only by the appended claims.

Reference in the specification to “one embodiment” or “an embodiment” or“some embodiments” means that a particular feature, structure, orcharacteristic described in conjunction with the embodiment can beincluded in at least one embodiment. Unless otherwise noted or requiredby context, characteristics of one embodiment are not mutually exclusivewith other embodiments. The appearances of the phrase “embodiment” invarious places in the specification do not necessarily all refer to thesame embodiment. It should be noted that there could be variations tothe flow diagrams or the operations described therein without departingfrom the embodiments described herein. For instance, operations can beperformed in parallel, simultaneously, or in a different order thatillustrated.

FIG. 1 illustrates, in block form, an overview of a system 100 forprocessing threads belonging to thread groups on a processor comprisinga plurality of core types each having one or more cores. The system 100can include hardware 110, operating system 120, user space 130, andsystem space 140 as described more fully below.

Hardware 110 can include a processor complex 111 with a plurality ofcore types or multiple processors of differing types. Processor complex111 can comprise a multiprocessing system having a plurality of clustersof cores, each cluster having one or more cores of a core type,interconnected with one or more buses. Processor complex 111 cancomprise an asymmetric multiprocessing (AMP) system having a pluralityof clusters of cores wherein at least one cluster of cores has adifferent core type than at least one other cluster of cores. Eachcluster can have one or more cores. Core types can include performancecores, efficiency cores, graphics cores, digital signal processingcores, arithmetic processing cores, neural processing cores, and othercore types. A performance core can have an architecture that is designedfor very high throughput and may include specialized processing such aspipelined architecture, floating point arithmetic functionality,graphics processing, or digital signal processing. A performance coremay consume more energy per instruction than an efficiency core. Anefficiency core may consume less energy per instruction than aperformance core. In an embodiment, processor complex 111 can comprise asystem on a chip (SoC) that may include one or more of the hardwareelements in hardware 110.

Hardware 110 can further include an interrupt controller 112 havinginterrupt timers for each core type of processor complex 111.

Hardware 110 can also include one or more thermal sensors 113. Hardware110 can additionally include memory 114, storage 115, audio processing116, one or more power sources 117, and one or more energy and/or powerconsumption sensors 118. Memory 114 can be any type of memory includingdynamic random-access memory (DRAM), static RAM, read-only memory (ROM),flash memory, or other memory device. Storage can include hard drive(s),solid state disk(s), flash memory, USB drive(s), network attachedstorage, cloud storage, or other storage medium. Audio 116 can includean audio processor that may include a digital signal processor, memory,one or more analog to digital converters (ADCs), digital to analogconverters (DACs), digital sampling hardware and software, one or morecoder-decoder (codec) modules, and other components. Hardware can alsoinclude video processing hardware and software (not shown), such as oneor more video encoders, camera, display, and the like. Power source 117can include one or more storage cells or batteries, an AC/DC powerconverter, or other power supply. Power source 117 may include one ormore energy or power sensors 118. Power sensors 118 may also be includedin specific locations, such as power consumed by the processor complex111, power consumed by a particular subsystem, such as a display,storage device, network interfaces, and/or radio and cellulartransceivers.

Operating system 120 can include a kernel 121 and other operating systemservices 127. Kernel 121 can include a processor complex scheduler 210for the processor complex 111. Processor complex scheduler 210 caninclude interfaces to processor complex 111 and interrupt controller112. Kernel 121, or processor complex scheduler 210, can include threadgroup logic 250 that enables the closed loop performance controller(CLPC) to measure, track, and control performance of threads by threadgroups. CLPC 300 can include logic to receive sample metrics fromprocessor complex scheduler 210, process the sample metrics per threadgroup, and determine a control effort needed to meet performance targetsfor the threads in the thread group. CLPC 300 can recommend a core typeand an allocated subset of that core type. CLPC 300 may also provideinformation used to determine a dynamic voltage and frequency scaling(DVFS) state for processing threads of the thread group and is discussedin greater detail below. Inter-process communication (IPC) module 125can facilitate communication between kernel 121, user space processes130, and system space processes 140.

User space 130 can include one or more application programs 131-133,closed loop thermal management (CLTM) 134, and one or more work intervalobject(s) 135. CLTM 134 can monitor a plurality of power consumption andtemperature metrics and feed samples of the metrics into a plurality oftunable controllers. A work interval object 135 is used to representperiodic work where each period has a deadline. The work interval object135 possesses a token and a specified time interval for one instance ofthe work. Threads that perform work of a particular type, e.g., audiocompositing, and the work must be completed in a specified interval oftime, e.g., a frame rate of audio, can be associated with the workinterval object 135. User space 130 can include a plurality of workinterval objects 135. A work interval object 135 can have its own threadgroup, as may be specified in source code, compiled code, or a bundle ofexecutables for execution. Threads that perform work on behalf of thework interval object 135 can opt-in to the thread group of the workinterval object 135. For threads that have opted-in and adopted thethread group of the work interval object 135, work performed by thethreads, on behalf of the work interval object 135, is associated withthe thread group of the work interval object 135 for purposes of CLPC300 operation.

System space 140 can include a launch daemon 141 and other daemons,e.g., media service daemon 142 and animation daemon 143.

CLPC 300 is a closed loop performance controller that determines, foreach thread group, a control effort needed to ensure that threads of thethread group meet their performance goals. A performance goal caninclude ensuring a minimum scheduling latency, ensuring a block I/Ocompletion rate, ensuring an instruction completion rate, maximizingprocessor complex utilization (minimizing core idles and restarts), andensuring that threads associated with work interval objects completetheir work in a predetermined period of time associated with the workinterval object. Metrics can be periodically computed by CLPC 300 frominputs sampled by CLPC 300 either periodically or through asynchronousevents from other parts of the system. In an embodiment, inputs can besampled at an asynchronous event, such as the completion of a workinterval object time period, or a storage event. A plurality ofperformance metrics can be computed within CLPC 300 and fed to one ormore tunable controllers to output a control effort needed for thethread group to meet its performance goals.

In an embodiment, a control effort is a unitless value in the range 0 to1 that can be used to determine a performance state associated with thethread group. Control effort may be used to determine a dynamic voltageand frequency scaling (DVFS) state and an allocated subset of availablecores of various types for the various processing units of the processorcomplex.

FIG. 2 illustrates, in block form, components of a closed loopperformance control (CLPC) system 300 of a system for processing threadshaving thread groups on a processor comprising a plurality of core typeseach having one or more cores, according to some embodiments. For eachof a plurality of thread groups 365 that have been active on a core,CLPC 300 can receive a sample of each of a plurality of performancemetrics. An “input” into CLPC 300 denotes information obtained by CLPC300 either by periodically sampling the state of the system or throughasynchronous events from other parts of the system. A “metric” iscomputed within CLPC 300 using one or more inputs and could be fed as aninput to its tunable controller and controlled using a tunable target. Ametric is designed to capture a performance trait of a workload. Aworkload is a set of computing operations (e.g., work items) to beperformed by a processor or co-processor. Input sources can include,e.g., animation work interval object (WIO) 301, audio WIO 302, blockstorage I/O 115, and processor complex 111. Example metrics from theinput sources can include work interval utilization 311 and 312, I/Otransaction rate 313, processor complex utilization 314, threadscheduling latency 315, and cluster residency 316. These metrics arebriefly summarized below and are described in greater detail inApplicant's co-pending U.S. patent application Ser. No. 15/996,469,entitled “Scheduler for AMP Architecture Using a Closed Loop Performanceand Thermal Controller,” which was filed on Jun. 2, 2018, and is herebyincorporated by reference in its entirety, together with the referencesincorporated therein.

Work interval utilization is a measure of proximity of thread completionto a user-visible deadline. Many workloads are targeted towards auser-visible deadline, such as video/audio frame rate. The processorcomplex 111 performance provided for such workloads needs to besufficient to meet the target deadlines, without providing excessperformance beyond meeting the respective deadlines, which is energyinefficient.

The I/O transaction rate metric computes the number of I/O transactionsmeasured over a sampling period and extrapolates it over a time period.An input/output (I/O) bound workload, such as block storage I/O 115,interacts heavily with non-processor complex subsystems such as storageor a network. Such workloads typically exhibit low processor complexutilization; however, the critical path of the workload includes sometime spent on the processor complex 111. A purpose of the processorcomplex utilization metric 314 is to characterize the ability of aworkload to exhaust the serial cycle capacity of the system at a givenperformance level, where the serial cycle capacity examines theutilization of the processor complex as a whole. The processor complexutilization metric 314 can be defined as a “running utilization”, i.e.,it captures the time spent on-core by threads. Processor complexutilization metric 314 can be sampled or computed from metrics providedby the processor complex scheduler 210.

Performing closed loop control around the processor complex utilizationmetric 314 for a thread group will give higher execution throughput tothis thread group once it eventually goes on-core, the idea being to tryand pull in the completion time of the threads of the thread group tobetter approximate what they would have been in an un-contended system.

Scheduling latency metric 315 can be provided by a processor complexscheduler. Scheduling latency 305, which can measure an amount oflatency that threads in a thread group experience between a time that athread of a thread group is scheduled and the time that the thread isrun on a core of the processor complex 111, can be sampled for a windowof time for a thread group and provided to CLPC 300 as a schedulinglatency metric 315. In one embodiment, thread scheduling latency metric315 serves as a proxy for the runnable utilization of a thread group ifrunnable utilization cannot be directly determined from the processorcomplex 111. The processor complex scheduler can determine when a threadof a thread group went on core, then off core. For all threads in thethread group, processor complex scheduler can determine how much timethe thread group spent running on cores. For each sampling period, CLPC300 can measure the maximum scheduling latency experienced by threads ofa thread group.

Each of the above metrics 311-315 can be fed to a tunable controller,e.g., 321-325 that outputs a contribution to a control effort forthreads of the thread group. Each tunable controller 321-325 can have atarget value, e.g., T_PT for working interval utilization 311, and atuning constant Ki. An integrator 340 sums the contributions andgenerates a unitless control effort for the thread group in the range of0 to 1 that is used as an index into a performance map 345.

Cluster residency metric 316 can be a cluster residency 306 sampled fora window of time for a thread group. Cluster residency 306 can measurean amount of time that threads of a thread group are resident on acluster of cores, such as E-cores or P-cores (or GPU cores, neuralengine cores, or other types of cores such as an image signal processor,a scaling and rotating engine, etc.). In an embodiment, clusterresidency metric 316 can have sample metric for each of one or morecluster of core types.

The CLPC 300 output is a control effort, an abstract value on the unitinterval (i.e., a value between 0 and 1) that expresses the relativemachine performance requirement for a workload. The control effort isused as an index into a performance map 345 to determine a recommendedcluster type (i.e., processing element type) and dynamic voltage andfrequency scaling (DVFS) state for the thread group. Recommended DVFSstates may be limited to reduce heat and/or to conserve power.

FIG. 3 illustrates a system 2200 to maintain performance metrics forworkloads spanning multiple agents, according to an embodiment. In thecontext of the embodiments described herein, an agent is a processingagent that can process workloads. The processor complex 111 is one typeof processing agent. Additional agents can include but are not limitedto a graphics processing unit (GPU) 2230, a neural engine 2235, and oneor more additional processors 2237, such as image signal processors,scaling and rotating engines, etc. In one embodiment, threads executingon the processor complex 111 can offload workloads to the GPU 2230,neural engine 2235, and additional processors 2237 that may residewithin the system 2200.

The processor complex 111 contains some number of CPU clusters, eachcluster containing some number of CPU cores. The clusters and cores aremanaged by the operating system 120, with the various CPU cores actingas application processors for programs executing on the operating system120. The GPU 2230 includes one or more graphics processor cores thatperform graphics specific operations. The GPU 2230 can additionally beconfigured to perform at least a subset of general-purpose processingoperations. The neural engine 2235 can be neural network accelerator oranother processing unit configured to perform processing operations forneural network algorithms. The neural engine 2235 is optimized forneural network acceleration, and also implements some basic primitivesthat can also be used for a subset of general-purpose operations. TheGPU 2230 and neural engine 2235 can perform operations at the request ofapplication processors within the processor complex 111. The additionalprocessors 2237 can include an image processor, a sensor processor, orother processing elements within the system 2200. While the GPU 2230 andneural engine 2235 are illustrated as separate from the processorcomplex 111, in some embodiments the GPU 2230, neural engine 2235, andother co-processors (e.g., image processors, sensor processors, etc.)can be integrated into the processor complex 111. In one embodiment, athread executing on an application processor can offload a workload bysubmitting a command buffer to the GPU 2230, neural engine 2235, oradditional processors 2237. The command buffer can include a set ofcommands to be performed on behalf of the submitting thread. Theco-processor can process the set of commands and return results to theprocessor complex 111.

The system 2200 additionally includes the CLPC 300, which acts as theperformance and power manager for the system. In some embodiments theCLPC 300 is integrated into the operating system 120, as illustrated inFIG. 1. In one embodiment, the CLPC 300 can be outside of the operatingsystem 120, as illustrated in FIG. 3. In one embodiment the operatingsystem 120 includes an I/O service 2210, which includes a set of systemlibraries and/or frameworks that can be adopted by drivers (e.g., GPUdriver 2220, neural engine driver 2225, additional processor drivers2227) that manage co-processors within the system 2200. The I/O service2210 allows other components of the operating system 120 and the CLPC tocommunicate messages with those drivers. The I/O service 2210 enablesthe operating system 120 to include work offloaded to co-processors aspart of a thread group, which enables CLPC 300 to track performance andefficiency metrics for workloads that span the CPU, GPU, and otherco-processors. In one embodiment, when a command buffer or another batchof commands is received at the GPU driver 2220, neural engine driver2225, or additional processor drivers 2227, the drivers can signal theCLPC 300 via the I/O service 2210 that a workload has been submitted forprocessing.

The signal can be performed by calling the CLPC 300 or a software moduleassociated with the CLPC 300. For example, the co-processor driver canuse the I/O service 2210 to call a WorkSubmit interface to indicatedetails about the submitted workload, as well as information on thesubmitting thread of the workload. The information on the submittedworkload can include a priority or quality of service classification forthe submitted workload and/or a priority or quality of serviceclassification associated with the submitting thread. The I/O Service2210 can then generate a token in response to the message, where thetoken is an identifier that can be used to tie metrics associated withthe offloaded workload to the submitting thread. For example, in oneembodiment the token can be used to identify the thread group associatedwith the submitting thread of the workload, where the thread group isthe repository of metrics associated with the group. In one embodiment,the token also keeps the thread group alive by taking a reference on thethread group object. Accordingly, even if all other references to thegroup are released while the workload has been offloaded to aco-processor, the thread group and associated metrics will remainallocated because of the reference associated with the token.

In one embodiment, upon beginning of the offloaded workload on theco-processor, the co-processor driver, or another thread associated withthe co-processor driver, can call a WorkBegin interface with the tokenreceived from the I/O service 2210. The CLPC 300 can tie the WorkBegincall to the previously WorkSubmit call using the token, even if thecalling thread group of WorkBegin differs from the calling thread groupof WorkSubmit. Upon completion of the workload, the co-processor driver,or an associated thread, can inform the CLPC 300 via a WorkEnd call thatalso includes the token. In one embodiment, the WorkBegin and WorkEndcall can each be used to return a collection of metrics for the workloadthat were gathered by the co-processor driver. In one embodiment, uponreceipt of the WorkEnd call, the CLPC 300 can retrieve metrics for theworkload from the co-processor driver. The CLPC 300 can then integratethe workload metrics into the performance and efficiency metrics for thesubmitting thread group. If the submitting thread is part of a threadgroup that is associated with a work interval object, adjustments can bemade to the DVFS state for the processor complex 111 or co-processorbased on processor performance relative to the WIO deadlines.Additionally, the reference on the thread-group object taken by thetoken is released during the WorkEnd call, allowing the thread-groupobject to be released if no other references are held.

It will be understood that the concepts described herein can be appliedto a system including any number of GPUs, neural engines, or otherco-processors, and are not limited to systems having a single instanceof these co-processors. Furthermore, when threads are offloaded from aprocessor to a co-processor, threads can offload work to some allocatedsubset of the available co-processor instances within the system, ratherthan using all available co-processor instances.

FIGS. 4-7 illustrate methods to track performance and efficiency metricsfor offloaded workloads, according to embodiments described herein. Theoffloaded workload metrics, in various embodiments, can include any ofthe thread execution metrics described herein, including work intervalutilization metrics. Thread execution metrics can additionally includetiming metrics, such as a time between initial submission of a commandbuffer and the beginning of command buffer execution and/or the timebetween WorkBegin and WorkEnd calls. The thread execution metrics canadditionally include a number of processor or co-processor cyclesbetween WorkBegin and WorkEnd calls, number of co-processor instructionsexecuted to perform the offloaded work, or other metrics that can beused to gauge co-processor efficiency or performance during execution ofthe offloaded workload.

Some operations described below can be performed by the hardware of aco-processor, firmware modules, or software modules associated with theco-processor. The methods can be used to track metrics for a variety ofco-processors, including but not limited to GPUs, neural engines, imageprocessors, audio processors, and other processors that can co-operatewith application processors within a computing system. Furthermore, insome embodiments the concepts described herein can be applied to anyvariant or type of accelerator devices, including scaler/rotator blocksor encoder/decoder blocks.

FIG. 4 illustrates a method 2300 to offload a workload to aco-processor, according to an embodiment. The method 2300 can beperformed by an application processor within a processor complex 111described herein, with some operations performed by software threadsexecuting on one or more application processors.

In one embodiment, the method 2300 includes operation 2302, whichexecutes threads of a thread group on a processor of the processorcomplex. A scheduler for the processor can schedule threads of thethread group on the recommended core type at the recommended DVFS statefor the thread group.

In operation 2304, one or more of the threads can determine to offload aworkload to a co-processor. The workload to offload may be a workloadmost suited for processing on the co-processor. For example, a graphicsprocessing workload can be offloaded to a GPU. A facial recognition orface detection workload can be offloaded to a general-purpose GPU(GPGPU) or another parallel compute engine, such as the GPU 2230 and/orneural engine 2235 of FIG. 3.

In operation 2306, the offloading thread of the thread group can submita command buffer to the co-processor. The offloading thread can submitthe command buffer via a driver associated with the co-processor, suchas a GPU driver 2220, a neural engine driver 2225, or another softwaredriver associated with the co-processor.

In operation 2307, the thread group can determine if any additional workis pending. If additional work is pending for the thread group, inoperation 2309 the thread group process the next workload. If noadditional work is pending, in operation 2311 the thread group can goidle and yield the processor to other threads. The application processorcan then process additional threads or go idle if no additional threadsare enqueued for processing.

In operation 2308, the thread group can receive notice of completion ofthe workload on the co-processor. Operation 2308 can be performed afterthe thread or thread group is resumed from an idle or sleep state if nowork was available for processing during the offload. As a result of thethread or thread group going idle, the processor on which the thread orthread group was executing may have been transitioned into a differentDVFS state.

In operation 2310, the thread or thread group can receive results of theoffloaded workload. As a result of performance and efficiency metricsgathered from the co-processor during the offload, the DVFS state of theprocessor executing the thread or thread group can be pre-adjusted tothe appropriate DVFS state to enable the efficient processing of thereceived results.

FIG. 5 illustrates a method 2400 of tracking performance metrics for anoffloaded workload, according to an embodiment. The method can beperformed by a CLPC as described herein (e.g., CLPC 300) to associatedperformance and/or efficiency metrics gathered for offloaded workloadswith the thread group associated with the offloaded workload.

Method 2400 includes operation 2402, in which the CLPC receives amessage indicating that a thread of a thread group is to offload aworkload to a co-processor. The message can be sent from theco-processor or co-processor driver in response to receipt of one ormore command buffers of commands to be executed on behalf of theoffloading thread. An identifier of the thread that is offloading theworkload can be received with the message. In one embodiment, themessage is, or is associated with, a WorkSubmit call into a softwareinterface for the CLPC. For example, a co-processor driver can use aninterface provided via the I/O service to call into a software interfaceof the CLPC.

In operation 2404 the CLPC can infer membership of the thread in thethread group based on an identifier of the thread using stored oraccessible information regarding thread groups and thread-groupmembership. In one embodiment, priority information associated with theworkload can also be determined from context information associated withthe thread group.

In operation 2406 the I/O service can issue a token to the co-processordriver. The token can be used to associate the workload with theinferred thread group. Some time period may lapse between the submissionof the workload to the co-processor and the beginning of workloadexecution on the processor. The token can be used to connect subsequentcalls regarding the workload to the initial WorkSubmit call, allowingdifferent threads or thread groups to issue WorkBegin and WorkEnd callson behalf of a workload. Internally, the CLPC can create data structureentries to record metrics for the workload. The metrics can be indexedwithin the data structure according to the token issued to theco-processor or co-processor driver. For example, the CLPC can record atimestamp associated with a time of submission of the workload to theco-processor. The timestamp can be stored in a data structure at alocation identified by the token or an identifier associated with thetoken. In one embodiment, the token can be an object associated withmetrics for the workload.

In operation 2408, the CLPC can receive notice of the beginning of theworkload on the co-processor, the notice including the issued token forthe workload. This notice can be associated with a WorkBegin call madevia the I/O service. In one embodiment the CLPC can record a timestampassociated with the beginning of the workload on the co-processor. Thenotice of the beginning of the workload on the co-processor can beprovided by a different thread group than the thread group that causedthe submission of the message in operation 2402.

In operation 2410, the CLPC can receive notice of completion of workloadon the co-processor, the notice including the issued token for theworkload. In one embodiment the CLPC can record a timestamp associatedwith the end of the workload on the co-processor.

In operation 2412, the CLPC can retrieve performance and/or efficiencymetrics for the completed workload. In one embodiment the performanceand/or efficiency metrics for the completed workload include timingmetrics for the submission, beginning, and end of processing for theworkload on the co-processor. In one embodiment, the metricsadditionally include performance and/or efficiency metrics gathered bythe co-processor or co-processor driver and submitted to the CLPC. Inone embodiment, performance metrics for the workload are stored inmemory accessible to the CLPC, which can retrieve the metrics for aworkload. In such embodiment, the metrics for a workload can be madeaccessible to the CLPC after the workload completes execution, althoughat least some of the metrics may be available during workload execution.Further in such embodiment, the stored metrics may be indexed by, orotherwise made accessible by an identifier based on the token issued bythe CLPC upon notice of submission of the workload.

At operation 2414, the CLPC can associate the performance and/orefficiency metrics for the completed workload with the thread group togenerate updated metrics for the thread group. The performance and/orefficiency metrics for the completed workload can be integrated with theexisting or historical metrics for the thread group.

At operation 2416, the CLPC can adjust a recommended core type and DVFSstate based on the updated performance and/or efficiency metrics. Basedon the performance metrics for the workload during execution on theco-processor, the thread group may be recommended for a different coretype and/or the DVFS state for the core executing the associated threadgroup can be adjusted. For example, under circumstances where theperformance of efficiency of workload execution on a co-processor can beimproved by increasing the frequency of the application processor, theDVFS state for the application processor can be adjusted. In oneembodiment, the CLPC can also adjust the DVFS state of the co-processoron which the workload is executed. Additionally, other techniques can beapplied to adjust the performance and/or efficiency of the co-processor,including limiting the number of co-processor cores used to execute aworkload, duty cycling the co-processor, or other techniques which canbe used to manage the performance, processing efficiency, or powerconsumption of a co-processor.

FIG. 6 illustrates an additional method 2500 of tracking performancemetrics for an offloaded workload, according to an embodiment. In oneembodiment, method 2500 can be performed by a driver associated with aco-processor, such as, but not limited to the GPU driver 2220 or neuralengine driver 2225 of FIG. 3, or a kernel thread group associated withsuch drivers. In other embodiments, logic within a co-processor, such asfirmware or microcontroller logic, can perform the method 2500. In suchembodiments, operations described below as being performed by theco-processor driver can be performed by an operating environmentexecuted on the co-processor.

In one embodiment, method 2500 includes operation 2502 to receive acommand buffer for a workload offloaded from a thread executing on anapplication processor, such as an application processor executing withinthe processor complex. For example, a thread on an application processorcan submit a buffer of commands to a GPU to render a window of a userinterface. A thread on the application processor can also submit abuffer of commands to a neural engine to perform a facial recognitionoperation. The command buffer can be received by a co-processor driver,which in one embodiment is also executing on the application processor.

In operation 2504, a thread group associated with the co-processordriver can call a WorkSubmit interface of the CLPC via the I/O service.The call can include an identifier of a thread associated with thecommand buffer received in operation 2502. The WorkSubmit interface canbe called via a software library or module that provides a softwareinterface to the CLPC. In one embodiment the co-processor driver canaccess the software interface to the CLPC via an I/O service (e.g., I/Oservice 2210) provided by an operating system of a computing systemdescribed herein (e.g., operating system 120 of system 2200). In oneembodiment, the WorkSubmit interface can be used to convey priority orquality of service information about the workload to be offloaded. Inone embodiment, priority or quality of service information can bedetermined automatically from context information of the submittingthread.

In operation 2506, the co-processor driver can receive a token toidentify the workload. The token can be used to tie the beginning andend of processing for the workload with the initial workload submitcall. In one embodiment the token can be used to index or identifyperformance metrics generated for the workload. While in one embodimentthe token is received from the I/O service, the token used to trackworkloads can be generated by other components within the system, suchas but not limited to the CLPC.

In operation 2508, the co-processor driver can prepare co-processorexecution logic to execute commands from the command buffer for theworkload. The co-processor driver can configure a thread dispatcher orscheduler on the co-processor to schedule internal co-processoroperations based on commands specified in the command buffer. Forexample, the internal co-processor operations can be performed byhardware threads within execution units of the co-processor. Theinternal execution architecture of the co-processor can vary betweenco-processors.

In one embodiment, as shown in operation 2510, a thread group associatedwith the co-processor driver can call a WorkBegin interface of the CLPCwhen the workload is ready to execute. The call to the WorkBegininterface can include the token or a reference to the token for theworkload. In one embodiment, the call to the WorkBegin interface can beperformed by a thread group of the operating system kernel. The kernelthread group can call the WorkBegin interface in conjunction withsubmitting a command buffer to the co-processor on behalf of theco-processor driver. In one embodiment, the call to the WorkBegininterface can be used to convey metrics about the current performancestate of the co-processor the CLPC. In one embodiment, metadata toenable estimation of amount of time it will take to perform a task canbe passed during the WorkBegin call. In one embodiment, currentco-processor load information can be conveyed during the WorkBegin call.In one embodiment, where multiple available co-processor or co-processorcores of a given type are available, the WorkBegin call can convey whichof the available co-processor cores will be used to process the workloadon the co-processor. The CLPC can use this submitted information tobalance the overall power consumption of the system while offloaded workis being performed.

The co-processor driver, in one embodiment, can perform an optionaloperation 2512 to track performance metrics of co-processor executionlogic associated with the work load. In addition to timestamp-basedmetrics gathered by the CLPC based on the WorkSubmit, WorkBegin, andWorkEnd calls, the co-processor may also record internal performancemetrics that can be gathered, recorded, or monitored by the co-processordriver. These performance metrics can be reported to the CLPC or storedin memory that is accessible by the CLPC.

In operation 2514, the co-processor driver can call a WorkEnd interfaceof the CLPC with the token when the workload completes execution.Optionally, performance metrics captured by the co-processor driver, ora reference (e.g., pointer) to such metrics, can be provided with or inassociation with the call to the WorkEnd interface of the CLPC.

FIG. 7 illustrates a method 2600 of tracking performance metrics for anoffloaded workload of a work interval object, according to anembodiment. Method 2600 can be performed when the thread group of theoffloading thread is associated with a Work Interval Object as describedherein. Method 2600 can be performed by a combination of operatingsystem components, hardware components, and software componentsassociated with the CLPC and co-processors.

The method 2600 includes operation 2602 to create a work interval objectassociated with a first thread group. A work interval object can becreated in several ways. There can be a set of predefined work intervalobjects in an operating system, daemon, framework, or application. Akernel of an operating system can create a work interval objectexplicitly, such as on behalf of a driver. A kernel of an operatingsystem can implicitly create a work interval object on behalf of anapplication, such as in response to an application call to a framework.

In operation 2604, the CLPC can receive a message indicating that athread of the thread group is to offload a workload to a co-processor.Operation 2604 can be performed in a similar manner as operation 2402 ofFIG. 5. For example, the message can be sent from the co-processor orco-processor driver in response to receipt of one or more commandbuffers of commands to be executed on behalf of the offloading threadand an identifier of the thread that is offloading the workload can bereceived with the message.

In operation 2606, the CLPC can infer membership of the thread in thethread group based on an identifier of the thread. In one embodiment,priority information associated with the workload can also be determinedfrom context information associated with the thread group.

In operation 2608, in response to the message, the I/O service used tointerface a co-processor driver with the CLPC can issue a token toassociate the workload with the work interval object. In operation 2610,the CLPC can receive notice of the beginning of the workload on theco-processor, the notice including the issued token for the workload. Inone embodiment the CLPC can record a timestamp associated with thebeginning of the workload on the co-processor. In operation 2612, theCLPC can receive notice of completion of workload on the co-processor,the notice including the issued token. In one embodiment the CLPC canrecord a timestamp associated with the end of the workload on theco-processor.

In operation 2614, the CLPC can assess performance metrics for thecompleted workload. Assessing the performance metrics can includeanalyzing timestamps recorded by the CLPC, or software associated withthe CLPC, in response to receipt of the WorkSubmit, WorkBegin, andWorkEnd. Those timestamps can be used to determine the time between thesubmission of the workload to the co-processor and the beginning of theworkload on the co-processor, as well as the time required to completethe workload on the co-processor.

In operation 2616, the CLPC can associate the performance metrics forthe completed workload with the thread group to generate updated metricsfor the thread group. The updated metrics can be generated byintegrating the new metrics with the existing or historical metrics forthe thread group.

At operation 2618, the CLPC can adjust a recommended core type and DVFSstate based on the updated performance metrics and target deadlines.Based on the performance metrics for the workload during execution onthe co-processor and the performance of the thread group relative to thework interval object deadlines, the thread group may be recommended fora different core type and/or the DVFS state for the core executing theassociated thread group can be adjusted. In one embodiment, the CLPC canalso adjust the DVFS state of the co-processor on which the workload isexecuted.

In one embodiment, to before adjusting the DVFS state of theco-processor on which the workload is executed to increase the voltageor frequency of that co-processor, the CLPC can reduce the voltage orfrequency of other co-processors within the system to keep an overallsystem power consumption below a threshold. For example, the voltage andfrequency of processors or co-processors within a system that are notactively performing operations can be reduced, while increasing thevoltage and frequency of other co-processors within the system.

In one embodiment, workloads offloaded to co-processors can be trackedon a per-instance basis. The token that is associated with a workloadcan be associated with a specific instance of the workload. For example,a WIO can be associated with a thread group that is to generate contentfor each frame to be displayed by a graphical system. Each frame to begenerated can be assigned a work interval instance identifier thatuniquely identifies the workload instance associated with that frame. Inone embodiment, metadata for each workload can be tracked on aper-instance basis. For example, a thread priority or quality of serviceclassification associated with the workload can be tracked on aper-frame basis.

In one embodiment, the instance identifier can be associated with thetoken that is provided by the I/O service in response to a call to theWorkSubmit interface. The instance identifier can be used to allowmetrics for multiple instances of workloads associated with the same WIOto be tracked. Enabling the tracking of separate instances of a WIOallows the generation of performance and efficiency metrics foragent-spanning workloads at a per-frame granularity. This per-framegranularity of metrics allows for fine-grained DVFS scaling across thevarious processing agents within a computing system.

In one embodiment, work interval instancing allows the tracking ofoffloaded metrics for pipelined work operations associated with anapplication. For example, a thread group for an application can pipelineworkloads for multiple frames of content. Work for each frame can betracked as a separate work instance interval. Tracking work intervalobjects on a per-frame, per-instance basis allows the CLPC to determinewhich of the individual frames that each portion of an application'soperations are associated with.

To summarize the foregoing, asymmetric multiprocessors (AMPs) canbenefit from the use of various performance metrics relating to thevarious system components to provide an appropriate level of performanceat a minimal power cost. One issue that could arise in prior artmultiprocessor systems is that various processors and coprocessors(e.g., CPUs, GPUs, neural engines, and other types of coprocessors) hadtheir own performance controllers that had no knowledge or limitedknowledge of the performance of other processors and coprocessors. Forexample, a CPU performance controller might have had little or noknowledge of or control over the processing specifics of an associatedcoprocessor, such as a GPU or neural engine. As a result, a CPU mightsubmit a workload to a coprocessor and, having no significant furtherworkload (at least until the coprocessor returns the completedworkload), transition to a lower power, lower performance state. (See,e.g., block 2311 of FIG. 4.)

In such a case, the CPU performance controller might ramp down theperformance of the CPU to a lower performance/lower power consumptionstate while the coprocessor was executing, only to have to ramp up againvery shortly thereafter when the workload returned from the coprocessor.Because transitioning power states requires a finite period of time, andbecause the CPU performance controller (e.g., CLPC 300) is largely abackwards-looking controller mechanism, a significant performancepenalty might be associated with this transition. Depending on thetiming involved, the amount of power saved might not justify theperformance penalty. Thus, in some cases it might be preferable to keepthe CPU in a higher performance state (even without additional workloadcurrently pending and even though more power would be consumed), becausethe increase in performance sufficiently offsets the increase in powerconsumption.

This objective may be achieved by adding a certain amount of hysteresisto the CPU performance controller (e.g., CLPC 300) to prevent the CPUfrom ramping down as quickly. This “Control Effort Hysteresis Approach”is described in greater detail below. As an alternative, rather thankeep the CPU in a higher performance state while waiting for thecoprocessor (which increases power consumption), it may be desirable toaccelerate the CPU's return to a higher performance state when theworkload returns from the coprocessor. This “Control Effort SeedingApproach” is also described in greater detail below.

Control Effort Hysteresis Approach

An exemplary CPU/GPU workload is illustrated in FIG. 8. Block 801represents a thread group executing on the CPU. At time t1, this threadgroup may be offloaded to a coprocessor, such as a GPU. The thread groupnow executing on the GPU is represented by block 802. At time t2, theGPU may have completed execution of the thread group, meaning the threadgroup returns to the CPU, where it is identified as block 803. At sometime t3, the thread group may again be offloaded to a coprocessor, whichmay be the same coprocessor as before or another coprocessor, where itis identified as block 804 before returning to the CPU again as block805 at time t4.

CPU control effort curve 806 illustrates a control effort parameter forthe CPU, which may be generated by CLPC 300 according to the varioustechniques described above and in the referenced co-pendingapplications. As can be seen in FIG. 8, the control effort for the CPUmay initially be at a relatively low value (e.g., a value of zero ornear zero) when the CPU is idle. As a thread group begins executing onCPU (represented by block 801), CLPC 300 may begin increasing thecontrol effort 806 according to the various feedback mechanismsdescribed above, until it reaches a relatively high value (e.g., a valueof one or near one). Once the thread group is passed to the GPU (whereit is represented by block 802), CLPC 300 may decrease the controleffort 806, as the CPU is basically idle while the GPU (or othercoprocessor) is executing the thread group.

Once the GPU is done with the thread group, it is returned to the CPU(where it is represented by block 803). At this point, CLPC 300 mayagain increase the thread group's CPU control effort 806 while thethread group is executing on the CPU and decrease the thread group's CPUcontrol effort 806 once the thread group is again offloaded to the GPU(where it is represented by block 804) as discussed above. This processmay repeat more or less continuously depending on workload.

GPU control effort curve 807 illustrates a control effort parameter forthe thread group on the GPU, which may be generated by a GPU performancecontroller according to principles corresponding to those discussedabove. It will be appreciated that in the illustrated exemplaryworkload, the control effort for the GPU is basically the inverse of thecontrol effort for the CPU, as the thread group is executing on one orthe other at various points in time, with the non-executing processorhaving no other workloads (in the illustrated example). In the casewhere there were other thread groups pending in the GPU pipeline, thenthe thread group's GPU control effort would remain high while executingthese other thread groups.

As discussed above, when the workload transfers from the CPU to acoprocessor (such as a GPU), the amount of time required for thereceiving processing unit's control effort to return to a higher levelcan impose an undesirable performance penalty. However, these effectsmay be mitigated by increasing an amount of hysteresis employed by CLPC300 in determining the control effort. This hysteresis may beimplemented separately for each processor and/or coprocessor, such thatcertain coprocessors may have higher, lower, or no hysteresis asappropriate for a given embodiment. FIG. 9 illustrates the workloaddescribed above with respect to FIG. 8 in which CLPC 300 employs ahigher degree of hysteresis to prevent the thread group's CPU controleffort 806 and the thread group's GPU control effort 807 from unwindingto the same degree. This hysteresis may be implemented in terms of adelay between the time at which a workload decrease occurs and the timeat which the control effort begins decreasing. This is illustrated inFIG. 9 as a delay time Tdelay between the end of a thread group'sexecution on a processing unit and the time at which the control effortbegins decreasing. Alternatively or additionally, the hysteresis may beimplemented as a decrease in the rate at which the control effortdecreases. This is illustrated in FIG. 9 as a decreased slope 901 of thedecaying control effort while the thread group is offloaded to thecoprocessor.

Review of FIG. 9 illustrates certain advantages of this approach. Forexample, when the thread group returns to the CPU, illustrated as block803, the increased hysteresis of the thread group's CPU control effort906 means that the control effort has not decreased all the way to zero.Thus, it takes control effort 906 less time to reach its peak value. Asa result of both the increased initial control effort and the decreasedtime to reach maximum control effort, the thread group will execute morequickly on return to the CPU. As illustrated in FIG. 9, the samehysteresis has been applied to the thread group's GPU control effort907. Thus, the same performance advantages are achieved with respect toexecution on the GPU.

FIG. 10 illustrates a flow chart of a processor/coprocessor controleffort management technique implementing increased hysteresis asdescribed above with respect to FIGS. 8 and 9. It will be appreciatedthat FIG. 10 generally corresponds to FIG. 4 discussed above, and thevarious processes may be implemented in substantially the same way,including the metric tracking techniques depicted in and described withreference to FIGS. 5-7.

FIG. 10 illustrates a method 1000 to offload a workload to aco-processor, according to an embodiment. The method 1000 can beperformed by an application processor within a processor complex 111described herein, with some operations performed by software threadsexecuting on one or more application processors.

In one embodiment, the method 1000 includes operation 1002, whichexecutes threads of a thread group on a processor of the processorcomplex. A scheduler for the processor can schedule threads of thethread group on the recommended core type at the recommended DVFS statefor the thread group.

In operation 1004, one or more of the threads can determine to offload aworkload to a co-processor. The workload to offload may be a workloadmost suited for processing on the co-processor. For example, a graphicsprocessing workload can be offloaded to a GPU. A facial recognition orface detection workload can be offloaded to a general-purpose GPU(GPGPU) or another parallel compute engine, such as the GPU 2230 and/orneural engine 2235 of FIG. 3.

In operation 1006, the offloading thread of the thread group can submitthe workload to the co-processor. For example, the offloading thread cansubmit the command buffer via a driver associated with the co-processor,such as a GPU driver 2220, a neural engine driver 2225, or anothersoftware driver associated with the co-processor.

In operation 1007, the thread group can determine if any additional workis pending. If additional work is pending for the thread group, inoperation 1009 the thread group process the next workload. If noadditional work is pending, the thread group can determine whether thethread group is anticipated to be returning from the co-processor withina certain time frame. If not, in operation 1011 the thread group can goidle and yield the processor to other threads. Alternatively, if thethread group is anticipated to return within a certain time period, inprocess 1012, the processor can go idle with hysteresis as depictedabove in FIGS. 8 and 9. The application processor can thus processadditional threads or go idle if no additional threads are enqueued forprocessing.

In operation 1008, the thread group can receive notice of completion ofthe workload on the co-processor. Operation 1008 can be performed afterthe thread or thread group is resumed from an idle or sleep state if nowork was available for processing during the offload. As a result of thethread or thread group going idle, the processor on which the thread orthread group was executing may have been transitioned into a differentDVFS state.

In operation 1010, the thread or thread group can receive results of theoffloaded workload. As a result of performance and efficiency metricsgathered from the co-processor during the offload, the DVFS state of theprocessor executing the thread or thread group can be re-adjusted to theappropriate DVFS state to enable the efficient processing of thereceived results.

Turning back to FIGS. 8 and 9, it will be appreciated that employing thecontrol effort hysteresis techniques described above can result in asignificant increase in power consumption because both the processor andcoprocessor may be kept in a higher DVFS state than warranted by theinstantaneous workload of the processor or coprocessor. Thus, in someembodiments it may be better to allow the processor or coprocessorworkload to wind down without hysteresis, but to save the control effortstate so that it may be more rapidly restored when the thread groupreturns to the processor/coprocessor. This control effort seedingapproach is described more thoroughly below.

Control Effort Seeding Approach

FIG. 11 illustrates an exemplary CPU/GPU workload like that depicted inFIG. 8, but in which the control effort for a given thread group isstored when the thread group is offloaded to a coprocessor and restoredwhen the thread group returns from the coprocessor. As can be seen inFIG. 11, the control effort for the CPU may initially (i.e., at thebeginning of block 801) be at a relatively low value (e.g., a value ofzero or near zero) when the CPU is idle. As a thread group beginsexecuting on CPU (represented by block 801), CLPC 300 may beginincreasing the control effort 806 according to the various feedbackmechanisms described above, until it reaches a relatively high value(e.g., a value of one or near one). Once the thread group is passed tothe GPU (where it is represented by block 802), if it is known ordetermined that the thread group will return from the GPU (or othercoprocessor) for further processing, CLPC 300 may store the controleffort 1108 a at time t1 and then decrease the control effort 806, as,in the illustrated workload, the CPU is basically idle while the GPU (orother coprocessor) is processing the thread group.

Once the GPU is done with the thread group, it is returned to the CPU(where it is represented by block 803) for further processing. At thispoint, CLPC 300 may retrieve the stored control effort 1108 a andrapidly increase the control effort to 1110 a (corresponding to thestored value 1108 a). This increase may be more rapid than the normalCLPC control loop, as indicated by the increased slope 1109 of threadgroup's CPU control effort curve 1106. When the CPU is again ready tooffload the thread group to the GPU, but it is known that the threadgroup will return for further processing, then a further control effortvalue 1108 b may be stored, and when the thread group again returns fromthe coprocessor (805), the control effort may again be rapidly increasedto a corresponding value 1110 b. The same principles may be applied tothe thread group's GPU control effort curve 1107, as depicted in thelower portion of FIG. 11.

FIG. 12 illustrates a flow chart of a processor/coprocessor controleffort management technique implementing control effort seeding asdescribed above with respect to FIG. 11. It will be appreciated thatFIG. 10 generally corresponds to FIGS. 4 and 10 discussed above, and thevarious processes may be implemented in substantially the same way,including the metric tracking techniques depicted in and described withreference to FIGS. 5-7.

FIG. 12 illustrates a method 1200 to offload a workload to aco-processor, according to an embodiment. The method 1200 can beperformed by an application processor within a processor complex 111described herein, with some operations performed by software threadsexecuting on one or more application processors.

In one embodiment, the method 1200 includes operation 1202, whichexecutes threads of a thread group on a processor of the processorcomplex. A scheduler for the processor can schedule threads of thethread group on the recommended core type at the recommended DVFS statefor the thread group.

In operation 1204, one or more of the threads can determine to offload aworkload to a co-processor. The workload to offload may be a workloadmost suited for processing on the co-processor. For example, a graphicsprocessing workload can be offloaded to a GPU. A facial recognition orface detection workload can be offloaded to a general-purpose GPU(GPGPU) or another parallel compute engine, such as the GPU 2230 and/orneural engine 2235 of FIG. 3.

In operation 1206, the offloading thread of the thread group can submitthe work load to the co-processor. For example, the offloading threadcan submit the command buffer via a driver associated with theco-processor, such as a GPU driver 2220, a neural engine driver 2225, oranother software driver associated with the co-processor.

In operation 1207, the thread group can determine if any additional workis pending. If additional work is pending for the thread group, inoperation 1209 the thread group process the next workload. If noadditional work is pending, the thread group can determine whether theoffloaded thread group is anticipated to be returning from theco-processor for further processing. If not, in operation 1211 thethread group can go idle and yield the processor to other threads.Alternatively, if the thread group is anticipated to return for furtherprocessing, in process 1212, the processor can go idle with a storedcontrol effort as described above with respect to FIG. 11. Theapplication processor can thus process additional threads or go idle ifno additional threads are enqueued for processing.

In operation 1208, the thread group can receive notice of completion ofthe workload on the co-processor. Operation 1208 can be performed afterthe thread or thread group is resumed from an idle or sleep state if nowork was available for processing during the offload. As a result of thethread or thread group going idle, the processor on which the thread orthread group was executing may have been transitioned into a differentDVFS state.

In operation 1210, the thread or thread group can receive results of theoffloaded workload. As a result of performance and efficiency metricsgathered from the co-processor during the offload, the DVFS state of theprocessor executing the thread or thread group can be pre-adjusted tothe appropriate DVFS state to enable the efficient processing of thereceived results.

Alternatively, if a control effort was stored in block 1212, uponreceipt of notice of work item completion on the coprocessor (block1214), the control effort can be reset to the stored control effort inprocess 1216. The processor can then receive the results of theoffloaded workload in process 1210 b and can perform the furtherprocessing at the restored control effort in block 1218.

The basic control effort seeding approach described above may beimproved by the use of serialization-based control to modify the amountof control effort seeding that is applied depending on the serializationof the workload. FIG. 13A-13C illustrate three workloads exhibitingdifferent degrees of serialization.

FIG. 13A illustrates a workload that is completely serialized, meaningthat the thread group is executing entirely on the CPU or entirely onthe coprocessor (e.g., a GPU), but never on both. This workloadcorresponds to the workload discussed above with respect to FIG. 8. Awork instance 1301 a of a thread group executes on a processor (e.g., aCPU), and, at time t1, is offloaded to a coprocessor (e.g., a GPU) whereit becomes work instance 1301 b. When the coprocessor completes workinstance 1301 b, it returns the result to the processor, which mayoperate on the returned data as work instance 1303 a and so on. Asmentioned above, this load is completely serialized. With suchserialized workloads it may be desirable to use the control effortseeding techniques described above to provide enhanced processingperformance.

FIG. 13B illustrates a workload that is perfectly pipelined, as opposedto completely serialized). In the illustrated perfectly pipelinedworkload, the processor (e.g., a CPU) executes a work instance 1301 acorresponding to the nth frame of a workload. As a non-limiting example,this could be generating a command buffer for the GPU coprocessor torender a frame of a video sequence. At time t1, the processor mayoffload the workload to a coprocessor (e.g., a GPU) as work instance1301 b, which also corresponds to the nth frame the workload. To extendthe non-limiting example, this could be the GPU performing the videoframe rendering from the received command buffer.

Unlike the completely serialized workload depicted in FIG. 13A, in theperfectly pipelined workload of FIG. 13B, the processor may, uponcompletion of work instance 1301 a begin work on work instance 1303 a,which may correspond to an n+1th frame of the work load. To extend thenon-limiting example above, this could be generating a command bufferfor the GPU to render a subsequent frame of the video. During the timethat the processor is executing work instance 1303 a, corresponding tothe n+1th frame of the workload, the coprocessor (e.g., a GPU) may beexecuting work instance 1301 b corresponding to the nth frame of theworkload. Thus, the CPU and GPU may be simultaneously processingdifferent portions of the thread group, with each processor running at ahigh degree of utilization. With such pipelined workloads, it may not bedesirable to use the control effort seeding techniques described above,as the control effort control techniques described with respect to FIGS.3 and 22-26 may provide acceptable performance.

FIG. 13C illustrates a workload that is somewhere between completelyserialized and perfectly pipelined, meaning that there is some degree ofpipelining between the processor and coprocessor (e.g., CPU and GPU),but in which there is some portion of time during which the processor(e.g., CPU) is waiting for the results of an offloaded work item fromthe coprocessor (e.g., GPU) or the coprocessor (e.g., GPU) is waitingfor a new command buffer from the processor (e.g., CPU). In theillustrative example of FIG. 13C, the processor requires less time toexecute its work instances 1301 a, 1303 a, 1305 a, and 1307 a than thecoprocessor requires to execute its corresponding work instances 1301 b,1303 b, 1305 b, and 1307 b. It will be appreciated that variations ofthis workload may also exist. For example, it could be that thecoprocessor completes its respective work instances more quickly thanthe processor such that the coprocessor ends up waiting for furtheroffloaded work instances from the processor. Additionally, the workloadcould be such that the processor executes other thread group tasks thatare not offloaded to the coprocessor, or are offloaded to anothercoprocessor, during the times that the processor is waiting on theillustrated coprocessor. This type of workload could fill in some of thegaps in the processor load, making it more resemble the perfectlypipelined workload of FIG. 13B.

In workloads like that depicted in FIG. 13C, some degree of controleffort seeding may be desirable, but it may perhaps not the same amountas would be applied in the completely serialized case depicted in FIG.13A. Thus, a degree of serialization parameter may be defined on theunit scale (i.e., a value between 0 and 1) with a value of 0corresponding to a perfectly pipelined workload as depicted in FIG. 13B,and 1 corresponding to a completely serialized workload as depicted inFIG. 13A. In such a system, the workload depicted in FIG. 13C might havea degree of serialization of 0.5, calculated as described in greaterdetail below.

In addition to the degree of serialization of a workload, it may bedesirable to alter the control effort seeding responsive to the lengthof time that the workload is executing on a processor or coprocessor. Tounderstand why, consider a first workload that has 50% serializationwith an 8 millisecond duration versus a second workload that has a 50%serialization but a 36 millisecond duration. In the former case, CLPC300 will have much less time (e.g., 8 ms) to reduce the control effortof the processor or coprocessor, and thus it may be the case that thecontrol effort will not have dropped to a level that control effortseeding would achieve any significant performance advantage. Conversely,in the latter case, CLPC 300 will have significantly more time (e.g., 36ms) to wind down the control effort of the processor or coprocessor. Inthis latter case, then, there may be significant performance advantagesto seeding the control effort as described above.

In addition to the degree of serialization and length of a workload, itmay be desirable to alter the control effort seeding responsive to atuning parameter that may be thought of as a “preference” or “efficiencyfactor.” As described in greater detail below, this tuning parameter maybe used to bias the control effort seeding in favor of increasedperformance or in favor of reduced power consumption. In someembodiments this parameter may be set responsive to a priority of aload. For example, high priority loads may be biased in favor ofincreased performance, while lower priority loads may be biased in favorof reduced power consumption. Additionally, this parameter may be setbased on other system parameters, such as available battery power,whether the task is a background task or a foreground, user-interactivetask, etc.

In some embodiments, a control effort floor for a processor may bedetermined based on the degree of serialization of a workload, theamount of time the workload is active on the coprocessor, and thetunable preference or efficiency factor. The control effort floor maycorrespond to the control effort to which the processor is returned whenan offloaded workload returns from a coprocessor. In the example of FIG.11 the control effort floor is 1110 a for work instance 803 and 1110 bfor work instance 805. In this example, the control effort floor wasequal to the stored control effort from the immediately preceding workinstance. However, as noted above, it may be desirable to adjust thecontrol effort floor responsive to the degree of serialization, time ofexecution, and a tuning factor based on other system requirements.

Therefore, FIG. 14 illustrates a flow chart for a method 1400 ofdetermining a control effort floor. The method begins with a process1402 in which a thread group is executed on a processor (e.g., instance1301 s of FIGS. 13A-13C). In subsequent process 1404, the thread groupis offloaded to a coprocessor (e.g., at time t1 in FIGS. 13A-13C). Whenthe thread is offloaded, CLPC 300 may sample the current control effort(e.g., control effort 1108 a in FIG. 11), the time at which the workloadinstance started on the coprocessor (e.g., t1), and the accumulated idleor busy time of the processor at time t1. Then, in process 1408, theprocessor waits for the workload to return from the coprocessor. In1410, CLPC 300 can sample the timestamp at the time the offloaded workinstance completed on the coprocessor (e.g., t2 in FIG. 13C) and theaccumulated idle or busy time of the processor at time t2.

In process 1414, CLPC 300 can determine the degree of serialization ofthe workload and the execution time. The execution time may bedetermined by the subtracting t1 from t2. The degree of serialization ofthe workload may be determined by dividing the processor busy timebetween t1 and t2 by the execution time. The processor busy time can bedetermined by subtracting the cumulative processor busy time sampled att1 from the cumulative processor busy time sampled at t2. (Acorresponding calculation could be made from measured idle times, withthe busy time being t2−t1 minus the difference in cumulative idle time.)Thus, in the workload of FIG. 13A, the processor busy time would be 0.The degree of serialization can be calculated as:

$S = {1 - \frac{t_{PB}}{t_{ex}}}$where t_(PB) is the processor busy time and S and t_(ex) are as definedabove. Thus, in the workload of FIG. 13A, the degree of serializationwould be 1, indicating complete serialization. In the workload of FIG.13B, the processor busy time would be t2 minus t1, which equals t_(ex),and thus the degree of serialization S would be 0, indicating perfectpipelining. In the workload of FIG. 13C, the processor busy time wouldbe approximately one half of t2−t1. Thus, the degree of serializationwould be approximately 0.5.

In process 1416, the control effort floor may be determined based on thedegree of serialization of a workload, the amount of time the workloadis active on the coprocessor, and the tunable preference or efficiencyfactor. More specifically, the control effort floor may be determinedaccording to the formula:CE_(fl) =S×ƒ(t _(ex))×α×CE_(st)where CE_(fl) is the control effort floor, S is the degree ofserialization of the workload, ƒ(t_(ex)) is a function ƒ of theexecution time t_(ex) of the workload on the coprocessor, a is thetuning parameter discussed above, and CEst is the stored control effortwhen the workload is offloaded. Other formulas could also be used ifappropriate for a given embodiment. The control effort floor is a valuethat may be used to seed the integrator of CLPC 300 that sets thecontrol effort parameter.

The function ƒ may take on any of a variety of forms. In someembodiments ƒ may be a linear function having a value 0 at some minimumtime that may be determined with respect to the CLPC sample rate andother system parameters and having a value 1 at some maximum timedetermined as a function of the expected range of execution times forthe various workloads. In other embodiments, ƒ may be a thresholdfunction that takes on a value of zero for work instances having a joblength less than a threshold and a value of one for work instanceshaving a job length (t_(ex)) greater than a threshold. For such afunction, the control effort floor would thus be zero for jobs shorterthan the threshold, meaning that no control effort seeding would beapplied. Similarly, the control effort floor would thus be implementedfor jobs longer than the threshold, meaning that the control effortwould be seeded to a degree determined by the degree of serialization ofthe work load and the tuning parameter as discussed elsewhere herein.

Using the formula of the preceding paragraph, assuming perfectserialization, S would have a value of 1. Assuming that the executiontime was sufficient to maximize the function fat its value of 1 and thetuning parameter a was also set at 1 (e.g., for a high priority, userinteractive process), then the control effort floor CE_(fl) would be setto the same as it was when the thread group was offloaded to thecoprocessor, i.e., CE_(st). Conversely, for a perfectly parallelworkload, the degree of serialization S would have a value of zero, andthe control effort floor would also be zero. Similarly, for a workloadin which the execution time t_(ex) on the coprocessor was sufficientlylow, ƒ(t_(ex)) would have a value of zero, also corresponding to a zerovalue for the control effort floor. Likewise, if the tuning parameter awere set to zero, corresponding to a low priority or background process,then the corresponding control effort floor would be zero. Finally, forvalues of the degree of serialization S, the function of the executiontime ƒ(t_(ex)), and the tuning parameter a falling between these values,the control effort floor will be set to some fraction of the storedcontrol effort at the time the workload was offloaded to thecoprocessor.

Deadline Driven Control

There are many types of computing workloads that must be completed by adeadline, but for which it may not be desirable to expend unduecomputational resources to complete the workload as soon as possible. Anexample of such workloads is playback of audio and/or video media in amobile device. If a particular frame of audio or video data is notdecoded and rendered in time, playback interruption or other undesirableeffects may result. On the other hand, because a mobile device oftenrelies on a finite amount of battery power, unnecessarily increasingprocessor or coprocessor performance beyond what is necessary to meetthe deadline results in unnecessary power consumption that provides noadvantage if the computational results are finished before they areneeded. Thus, for these types of workloads, it may be desirable toadjust the performance of the processor(s) and/or coprocessor(s) so thatthe computational workload is completed before, but as close aspossible, to some deadline.

Historically, single processor systems have relied on an API providinginformation such as a start timestamp for a work interval, a finishtimestamp for the work interval, and a deadline for the work interval. Awork interval is repeating portion of work that executes on a processor.The deadline could be expressed as either an absolute time of completionor as an amount of computation time available. When a work interval iscompleted, the difference between the absolute deadline and the time ofcompletion, or between the allotted time and the actual time used, canbe used as an error signal for a CLPC to servo processor performance(e.g., dynamic voltage and frequency state or DVFS) so that workloadsare completed meeting deadlines with a little time to spare. This typeof control works well for single processor or homogenous multiprocessorsystems but may not be sufficient for heterogenous multiprocessorsystems.

The problem may be understood with reference to FIG. 15, whichillustrates an exemplary workload for in a multiprocessor system likethat illustrated in FIG. 3, having a processor complex (Pr) (e.g.,processor complex 111) and first and second coprocessors Cp1 and Cp2(e.g., GPU 2230 and neural engine 2235). It will further be appreciatedthat this arrangement is merely exemplary, various numbers and types ofprocessors and coprocessors could also be used. Additionally, for easeof discussion, the workload illustrated in FIG. 15 is a completelyserialized workload, although the load may be also be pipelined.

In any case, the work interval starts on processor Pr with work instance1501 being performed by the processor. At time t1, the workload isoffloaded to coprocessor Cp1 (e.g., GPU 2230) as work instance 1503. Attime t2, coprocessor Cp1 has completed work instance 1503, and theworkload is returned to processor Pr as work instance 1505. At time t3processor Pr completes work instance 1505 and offloads the workload tocoprocessor Cp2 (e.g., neural engine 2235) as work instance 1507. Attime t4, coprocessor Cp2 completes work instance 1507, and the workloadreturns to processor Pr as work instance 1509, with completion of theentire work interval occurring at time t5. In this example, the totalexecution time of the work interval is t5−t0. The total time onprocessor Pr time is t1−t0+t3−t2+t5−t4. The total time on coprocessorCp1 is t2−t1, and the total time on coprocessor Cp2 is t4−t3.

For sake of discussion, assume the completion deadline for theillustrated work interval was time t6. Because the deadline is missed, aprior art CPU scheduler would speed up processor Pr. However, this mightnot be a suitable strategy. First, because of the relatively shortamount of time the workload spends on processor Pr as compared to thetwo coprocessors Cp1 and Cp2, a significant performance increase ofprocessor Pr (and thus substantially increased power consumption) mightbe necessary to complete the entire work interval before the deadline.As a result, these prior art systems might substantially increase powerconsumption without making an appreciable improvement in the ability ofthe system to meet the deadlines. However, by expanding thefunctionality of CLPC 300 to directly monitor and control and/orinfluence performance of each of the different processing units of thesystem (e.g., processor Pr and coprocessors Cp1 and Cp2), thesedisadvantages may be avoided.

An alternative way of illustrating the workload and associated processorperformance issues is illustrated in FIG. 15B. FIG. 15B illustrates theCPU portion 1521 of a workload and the GPU portion 1522 of the sameworkload. The workload has a completion deadline 1524, which may be atime at which the processing must be completed to avoid undesirableeffects (such as playback skips when decoding audio and/or videoinformation). To ensure completion deadlines are met, there may be acompletion target 1523 provided, which is slightly in advance of thedeadline. The time difference between actual completion of the workload(1521 b, as discussed below) and the target is the error 1526.

CPU portion 1521 of the workload begins at time 1521 a and ends at time1521 b. GPU portion 1522 of the workload begins at time 1522 a and endsat time 1522 b. The beginning and end times of each processing agentportion may be delivered to the CLPC using the techniques describedabove. From these start and end times, the CLPC may determine the CPUcritical time 1521 c (i.e., the time during which only the CPU isworking on the workload/thread group) and the GPU critical time 1522 c(i.e., the time during which only the GPU is working on theworkload/thread group). Critical utilization is discussed in greaterdetail below. A shared time 1525 is the time period when neitherprocessing element is the critical processing element. Although FIG. 15illustrates an arrangement with two processing elements (i.e., a CPU anda GPU) and a single workload/thread group, it will be appreciated thatthe same principles may be extended to a multiplicity of processingelements, including multiple processor cores of a given type, as well asmultiple thread groups.

Turning back to FIG. 3, and with continued reference to FIG. 15B, CLPC300 may ascertain the start and end times for each work interval on theCPU (e.g., 1501, 1505, and 1509) using the input/output performance APIcalls discussed above and in the cross-referenced co-pendingapplications. Additionally, GPU driver 2220 and neural engine driver2225 may communicate with I/O service 2210 to execute their own inputoutput performance calls when a work instance starts or finishes ontheir respective processors. This information may then be used by theoperating system 120 (or by CLPC 300) to ascertain the total utilizationtime of each agent in the multiprocessor system. Knowing the totalutilization time of each agent (e.g., CPU, GPU, neural engine, etc.)provides some insight into how the total system performance may beimproved to meet the deadline. For example, if it is known that the workinterval spends most of its time on one of the coprocessors, then CLPCmay increase the performance of that coprocessor, e.g., by increasingits frequency/voltage to gain higher performance. An example of thisprocess is illustrated in FIG. 16A.

FIG. 16A illustrates a method 1600 a that may be performed by CLPC 300,operating in conjunction with operating system 120 (e.g., I/O service2210 and various agent drivers 2220, 2225, and 2227 illustrated in FIG.3) for adjusting the performance of various agents in a multiprocessorsystem. The method begins with process 1602, which includes executing awork interval on the multi-agent system. In process 1604, the executiontime for each agent to complete the work interval may be determined. Itis then determined whether the deadline for the work interval was met(1606). If not, then, in process 1610 a, the performance of the agentwith the longest execution time may be increased. Longest execution timemay be measured either by the total execution time for each agent or maybe measured as a fraction of each agent's run time as a total of thetotal work interval execution time. The performance increase applied inprocess 1610 a may be a discrete step increase along a ladder of fixedperformance states, or may be a proportional, integral, orproportional-integral controller depending on the particularimplementation. In other embodiments, the performance increase may bedetermined by a scalability model, as described in greater detail belowwith respect to FIG. 19. In any case, the system continues with process1614 to execute the next work interval.

Alternatively, if the result of test 1606 is that the deadline was met,it may be determined whether the deadline was met too soon. For example,there may be a headroom threshold associated with the deadline. Thisheadroom threshold may be an absolute amount of time or may be apercentage of the job length. If the workload completes within theheadroom threshold (the no branch), then the deadline was not met toosoon, no adjustment is necessary, and the system may execute the nextwork interval in process 1614 without further performance adjustment.Alternatively, if the workload completes outside the headroom threshold(the yes branch), then the deadline was met too soon. In this case,process 1616 a can decrease the performance of the agent with theshortest execution time (thereby lengthening the total computationtime). The performance decrease applied in process 1616 a may be adiscrete step decrease along a ladder of fixed performance states, ormay be a proportional, integral, or proportional-integral controllerdepending on the particular implementation. In other embodiments, theperformance decrease may be determined by a scalability model, asdescribed in greater detail below with respect to FIG. 19. The systemmay then continue executing the next work interval with the decreasedperformance (process 1614).

While the foregoing algorithm adjusts only a single processing agent,the same principles may be used to adjust each processing agentaccording to the algorithm depicted in FIG. 16B. As above, the methodbegins with process 1602, which includes executing a work interval onthe multi-agent system. In process 1604, the execution time for eachagent to complete the work interval may be determined. It is thendetermined whether the deadline for the work interval was met (1606). Ifnot, then, in process 1610 b, the performance of each agent is increasedin proportion to its fraction of the total execution time. In otherwords, an agent that was being utilized for 40% of the total executiontime of a work interval will have 40% of the increase it would otherwisereceive if it were the sole element being adjusted according to thetechnique described above with respect to FIG. 16A. The performanceincrease applied in process 1610 b may be a discrete step increase alonga ladder of fixed performance states, or may be a proportional,integral, or proportional-integral controller depending on theparticular implementation. In other embodiments, the performanceincrease may be determined by a scalability model, as described ingreater detail below with respect to FIG. 19. In any case, the systemcontinues with process 1614 to execute the next work interval.

Alternatively, if the result of test 1606 is that the deadline was met,it may be determined whether the deadline was met too soon. For example,there may be a headroom threshold associated with the deadline. Thisheadroom threshold may be an absolute amount of time or may be apercentage of the job length. If the workload completes within theheadroom threshold (the no branch), then the deadline was not met toosoon, no adjustment is necessary, and the system may execute the nextwork interval in process 1614 without further performance adjustment.Alternatively, if the workload completes outside the headroom threshold(the yes branch), then the deadline was met too soon. In this case,process 1616 b can decrease the performance of each agent in proportionto its share of the total execution time (thereby lengthening the totalcomputation time). The performance decrease applied in process 1616 bmay be a discrete step decrease along a ladder of fixed performancestates, or may be a proportional, integral, or proportional-integralcontroller depending on the particular implementation. In otherembodiments, the performance decrease may be determined by a scalabilitymodel, as described in greater detail below with respect to FIG. 19. Thesystem may then continue executing the next work interval with thedecreased performance (process 1614).

The technique described above may provide some performance improvementover prior art systems, in that the performance of each agent may beindividually altered. However, the system may be further optimized byconsidering more than the total run time of each agent. Morespecifically, it may be desirable to determine the critical run time ofeach agent (i.e., the time during which only that agent is working onthe thread group) and the power efficiency of each agent.

Critical Utilization of Each Agent

For any less than perfectly pipelined workload spanning multiple agents(i.e., different processors or coprocessors), there will be at least onecritical agent for at least a portion of the execution time of a workinterval. A critical agent is an agent that is processing a workinterval while none of the other agents is working on that interval. Inmany workloads, each agent will be a critical agent for at least aportion of the work interval. In a perfectly serialized workload, eachagent is always a critical agent. Critical run time for an agent may bedefined as the run time of an agent during which none of the otheragents are processing the work interval. Critical utilization for anagent is the total of the critical run time for the agent during thework interval. Reducing the critical utilization of one or more agentscan be a more optimal way in which to improve deadline performance.

More specifically, reducing the critical utilization of an agentprovides a directly corresponding reduction in the total run time of thework interval. In other words, reducing the critical utilization of anagent by a certain amount of time t will result in reducing the totalrun time of the work interval by the same time t. This is because theremaining agents will spend t less time waiting on the critical agentbut will still be able to complete their portion of the workload in thesame time it would otherwise have taken. Conversely, reducingnon-critical utilization of an agent by an amount of time t may resultin a reduction in the total run time by less than t. In some cases,there may be no reduction at all in the total run time. It will beappreciated that reducing non-critical utilization of an agent mayresult in an intermediate result being ready before a subsequent agentis ready for it, thus providing no benefit in reducing the total runtime.

Thus, the deadline driven control algorithm depicted in FIGS. 16A and16B may be enhanced by identifying the agent having the highest criticalutilization and increasing the performance of that agent if necessary tomeet a deadline. Critical utilization of an agent may be determined byCLPC 300. More specifically, CLPC 300 may have a run counter for eachagent (e.g., CPU, GPU, neural engine, etc.) This run counter will tellCLPC 300 how many and threads are running on the respective agent and towhich thread groups these threads belong. From this information, CLPC300 can tell when an agent is the critical agent. For example, for agiven thread group, when the run count for the CPU is non-zero, and thethread counts for the other agents are zero, the CPU can be determinedto be the critical agent. As described above with respect to FIGS. 15,16A and 16B, CLPC 300 may also know the start and stop times for eachwork instance on each respective agent. By correlating this data, CLPC300 may determine critical run time for each agent. By summing thecritical run times for each agent over execution of the entire workinterval and dividing by the total run time for the work interval,critical utilization for each agent may be determined. Then, ifperformance of the system is insufficient to meet a deadline,performance of the agent having the highest critical utilization may beincreased as described below with respect to FIG. 17A. Alternatively, ifthe performance of the system is so high that deadlines are being mettoo soon (resulting in power inefficiency), the performance of the agentwith the lowest critical utilization may be decreased as described belowwith respect to FIG. 17A.

FIG. 17A illustrates a method 1700A that may be performed by CLPC 300,operating in conjunction with operating system 120 (e.g., I/O service2210 and various agent drivers 2220, 2225, and 2227 illustrated in FIG.3) for adjusting the performance of various agents in a multiprocessorsystem. The method begins with process 1702, which includes executing awork interval on the multi-agent system. In process 1704, the criticalutilization for each agent may be determined as described above. It isthen determined whether the deadline for the work interval was met(1706). If not, then, in process 1710 a, the performance of the agentwith the highest critical utilization may be increased. This effectivelyreduces the amount of time that the other agents must spend waiting onthe most critical agent. The performance increase applied in process1710 a may be a discrete step increase along a ladder of fixedperformance states, or may be a proportional, integral, orproportional-integral controller depending on the particularimplementation. In other embodiments, the performance increase may bedetermined by a scalability model, as described in greater detail belowwith respect to FIG. 19. In any case, the system continues with process1714 to execute the next work interval.

Alternatively, if the result of test 1706 is that the deadline was met,it may be determined whether the deadline was met too soon. For example,there may be a headroom threshold associated with the deadline. Thisheadroom threshold may be an absolute amount of time or may be apercentage of the job length. If the workload completes within theheadroom threshold (the no branch), then the deadline was not met toosoon, no adjustment is necessary, and the system may execute the nextwork interval in process 1714 without further performance adjustment.Alternatively, if the workload completes outside the headroom threshold(the yes branch), then the deadline was met too soon. In this case,process 1716 a can decrease the performance of the agent with the lowestcritical utilization, thus increasing the amount of time that the otheragents will spend waiting on this element. The performance decreaseapplied in process 1716 a may be a discrete step decrease along a ladderof fixed performance states, or may be a proportional, integral, orproportional-integral controller depending on the particularimplementation. In other embodiments, the performance decrease may bedetermined by a scalability model, as described in greater detail belowwith respect to FIG. 19. The system may then continue executing the nextwork interval with the decreased performance (process 1714).

While the foregoing algorithm adjusts only a single, most criticalprocessing agent, the same principles may be used to adjust eachprocessing agent according to its degree of criticality using analgorithm like that depicted in FIG. 17B. FIG. 17B illustrates a method1700 b which may be performed by CLPC 300, operating in conjunction withoperating system 120 (e.g., I/O service 2210 and various agent drivers2220, 2225, and 2227 illustrated in FIG. 3) for adjusting theperformance of various agents in a multiprocessor system. The methodbegins with process 1702, which includes executing a work interval onthe multi-agent system. In process 1704, the critical utilization foreach agent may be determined as described above. It is then determinedwhether the deadline for the work interval was met (1706). If not, then,in process 1710 b, the performance of each agent is increased inproportion to its degree of criticality. Degree of criticality may bedetermined by a ratio of the critical utilization of a given agent tothe total critical utilization for all agents. Thus, if a given workinterval has a total critical utilization of 100 ms (meaning that for100 ms of the work interval an agent was critical), and a given agentcontributed 40 ms to the total, that agent would have its performanceincreased by 40% of the performance increase it would receive if it werethe only element being adjusted. This effectively reduces the amount oftime that each agent is acting as the critical agent. The performanceincrease applied in process 1710 b may be a discrete step increase alonga ladder of fixed performance states, or may be a proportional,integral, or proportional-integral controller depending on theparticular implementation. In other embodiments, the performanceincrease may be determined by a scalability model, as described ingreater detail below with respect to FIG. 19. In any case, the systemcontinues with process 1714 to execute the next work interval.

Alternatively, if the result of test 1706 is that the deadline was met,it may be determined whether the deadline was met too soon. For example,there may be a headroom threshold associated with the deadline. Thisheadroom threshold may be an absolute amount of time or may be apercentage of the job length. If the workload completes within theheadroom threshold (the no branch), then the deadline was not met toosoon, no adjustment is necessary, and the system may execute the nextwork interval in process 1714 without further performance adjustment.Alternatively, if the workload completes outside the headroom threshold(the yes branch), then the deadline was met too soon. In this case,process 1716 b can decrease the performance of each agent in proportionto its degree of criticality (determined as described above). Theperformance decrease applied in process 1716 b may be a discrete stepdecrease along a ladder of fixed performance states, or may be aproportional, integral, or proportional-integral controller depending onthe particular implementation. In other embodiments, the performancedecrease may be determined by a scalability model, as described ingreater detail below with respect to FIG. 19. The system may thencontinue executing the next work interval with the decreased performance(process 1714).

Although the foregoing description assumes a single critical agent, itwill be appreciated that the criticality analysis may be conducted on apair-wise or other tuple-wise basis so as to ascertain criticality ofmore than one agent with respect to another agent or group of agents. Inthis case, the performance of the critical group of agents (rather thanjust a single agent) may be adjusted as described above. The algorithmdescribed above may be used to increase performance of a particularagent in a multiprocessor system in a way that most significantlyimproves the total performance of the system, e.g., how well it is ableto meet a deadline. However, in some cases a critical utilization-basedapproach may meet the deadlines in a way that is less power efficientthan some other performance adjustment that would also meet thedeadlines.

Power Efficiency of Each Agent

In modern computing systems, power consumption of the processing unitsmay be of high importance. This may be especially true in the case ofmobile systems that are limited to a finite amount of battery power.Thus, when increased performance is desired, power considerations may beemployed to achieve the required level of performance at minimal powercost.

Many modern processor systems include one or more digital powerestimators. For example, an analog power measurement circuit or adigital power estimator may be included for each agent of a multi-agentprocessing system. Thus, in the exemplary embodiment of FIG. 3, each ofprocessor complex 111, GPU 2230, neural engine 2235, and additionalprocessors 2237 may include their own power estimator. In someembodiments, digital power estimators may be implemented as afree-running, ever-increasing counter that continuously increments asthe agent is running. When the agent is running in a higher performancestate, the counter may be updated with a greater increment and/or morefrequently. When the agent is running in a lower performance state, thecounter may be updated with a smaller increment and/or less frequently.As a result, subtracting a digital power estimator sample from thebeginning of a work instance from a digital power estimator sample fromthe end of a work instance gives an indication of the energy consumed bythat agent in completing the work instance. Dividing the energy consumedby the length of time between beginning and end of the work instancegive an estimate of the power consumption of the agent. Thus, accordingto the principles described above, power consumed by each agent may beaccounted for in making the performance adjustments using either theexecution time/utilization algorithms described with respect to FIGS.16A and 16B or the critical utilization algorithms described withrespect to FIGS. 17A and 17B.

One way to incorporate power efficiency into any of these algorithms isby making a cost benefit comparison. The cost of a particular adjustmentto a particular agent may be considered to be the associated increase inpower consumption. The benefit of a particular adjustment to aparticular agent may be considered as the associated decrease inexecution time. This cost benefit ratio gives what may be considered anefficiency for each agent.

FIG. 18A illustrates a method 1800 a incorporating power efficiency intoa utilization-based performance control method similar to thatillustrated in FIGS. 16A and 16B. Method 180 a may be performed by CLPC300, operating in conjunction with operating system 120 (e.g., I/Oservice 2210 and various agent drivers 2220, 2225, and 2227 illustratedin FIG. 3) for adjusting the performance of various agents in amultiprocessor system. The method begins with process 1802, whichincludes executing a work interval on the multi-agent system. In process1804, the execution time for each agent to complete the work intervalmay be determined as well as the power consumption for each agent. It isthen determined whether the deadline for the work interval was met(1806). If not, then, in process 1810 a, the performance of each agentmay be increased in proportion to its efficiency. It will be appreciatedthat as the execution time of a given agent decreases, its efficiencywill increase, and as the power consumed by the agent decreases, itsefficiency will also increase. Furthermore, power consumed may beestimated over any number of past work intervals.

As above, the performance increase applied in process 1810 a may be adiscrete step increase along a ladder of fixed performance states, ormay be a proportional, integral, or proportional-integral controllerdepending on the particular implementation. In other embodiments, theperformance increase may be determined by a scalability model, asdescribed in greater detail below with respect to FIG. 19. In any case,the system continues with process 1814 to execute the next workinterval.

Alternatively, if the result of test 1806 is that the deadline was met,it may be determined whether the deadline was met too soon. For example,there may be a headroom threshold associated with the deadline. Thisheadroom threshold may be an absolute amount of time or may be apercentage of the job length. If the workload completes within theheadroom threshold (the no branch), then the deadline was not met toosoon, no adjustment is necessary, and the system may execute the nextwork interval in process 1814 without further performance adjustment.Alternatively, if the workload completes outside the headroom threshold(the yes branch), then the deadline was met too soon. In this case,process 1816 a can decrease the performance of each agent in proportionto its efficiency. The performance decrease applied in process 1816 amay be a discrete step decrease along a ladder of fixed performancestates, or may be a proportional, integral, or proportional-integralcontroller depending on the particular implementation. In otherembodiments, the performance decrease may be determined by a scalabilitymodel, as described in greater detail below with respect to FIG. 19. Thesystem may then continue executing the next work interval with thedecreased performance (process 1814).

FIG. 18B illustrates a method 1800 b incorporating power efficiency intoa criticality-based performance control method similar to thatillustrated in FIGS. 17A and 17B. Method 180 b may be performed by CLPC300, operating in conjunction with operating system 120 (e.g., I/Oservice 2210 and various agent drivers 2220, 2225, and 2227 illustratedin FIG. 3) for adjusting the performance of various agents in amultiprocessor system. The method begins with process 1802, whichincludes executing a work interval on the multi-agent system. In process1804, the critical utilization for each agent to complete the workinterval may be determined as well as the power consumption for eachagent. It is then determined whether the deadline for the work intervalwas met (1806). If not, then, in process 1810 b, the performance of eachagent may be increased in proportion to its efficiency. It will beappreciated that as the critical time of a given agent decreases, itsefficiency will increase, and as the power consumed by the agentdecreases, its efficiency will also increase. Furthermore, powerconsumed may be estimated over any number of past work intervals.

As above, the performance increase applied in process 1810 b may be adiscrete step increase along a ladder of fixed performance states, ormay be a proportional, integral, or proportional-integral controllerdepending on the particular implementation. In other embodiments, theperformance increase may be determined by a scalability model, asdescribed in greater detail below with respect to FIG. 19. In any case,the system continues with process 1814 to execute the next workinterval.

Alternatively, if the result of test 1806 is that the deadline was met,it may be determined whether the deadline was met too soon. For example,there may be a headroom threshold associated with the deadline. Thisheadroom threshold may be an absolute amount of time or may be apercentage of the job length. If the workload completes within theheadroom threshold (the no branch), then the deadline was not met toosoon, no adjustment is necessary, and the system may execute the nextwork interval in process 1814 without further performance adjustment.Alternatively, if the workload completes outside the headroom threshold(the yes branch), then the deadline was met too soon. In this case,process 1816 b can decrease the performance of each agent in proportionto its efficiency (thereby lengthening the total computation time). Itwill be appreciated that as the critical time of a given agentdecreases, its efficiency will increase, and as the power consumed bythe agent decreases, its efficiency will also increase. Furthermore,power consumed may be estimated over any number of past work intervals.The performance decrease applied in process 1816 b may be a discretestep decrease along a ladder of fixed performance states, or may be aproportional, integral, or proportional-integral controller depending onthe particular implementation. In other embodiments, the performancedecrease may be determined by a scalability model, as described ingreater detail below with respect to FIG. 19. The system may thencontinue executing the next work interval with the decreased performance(process 1814).

In the foregoing examples, power cost for each agent is determined as abackward-looking estimation. This backward-looking estimation may beadvantageous in that it may be easier to ascertain past powerconsumption over some known prior period of time than to estimate poweron a forward-looking basis. Nonetheless, any of the above-describedalgorithms could also be used with forward-looking power estimates. Ineither case, the objective is the same, which is to increase performancein a way that meets performance deadlines at a lowest energy cost.

In some embodiments, a forward looking power estimation may be made bydetermining or estimating a present frequency and voltage (i.e., powerconsumption) of an agent. Additionally, a measured or estimated activityfactor of the workload may be determined or estimated. For example, theactivity factor may be a fraction the workload versus the total workbeing done by the agent. Additionally, it may be useful to consider thepresent temperature of the agent. Then, a desired frequency and voltage(i.e., power consumption) of the agent may be estimated, along with anestimate of the new activity factor for the desired frequency voltagestate. Then, assuming that the desired power state would remain withinthe thermal constraints of the agent, it may be determined whether theincreased power “cost” is worth the increased performance.

Scalability Model Control

As noted above, for various deadline driven control schemes, theperformance state of a processing element, such as a CPU, a GPU, aneural engine, etc., may be determined by a scalability model. Ingeneral, the operating principle of a scalability model is based on theassumption that processing element frequency is inversely proportionalprocessing element run time. Thus, doubling the frequency of aprocessing element will half the run time of a task on that element,and, conversely, halving the frequency of a processing element willdouble the run time of a task on that element. It will be appreciatedthat this assumption holds only for a task that is 100% bound to theprocessing element in question and a workload that is 100% scalable. Aload that is less than 100% bound to the processing element is one thathas factors other than processing element performance limiting itsperformance. For example, I/O timing limitations may result in asituation where a task is less than 100% bound to the processing elementperformance or is less than 100% scalable. In any case, a controlleremploying a scalability model may increase a DVFS state of the processorin proportion to the amount of time by which a deadline associated witha thread group is missed or met too soon.

An example scalability model based control system is illustrated in FIG.19. Other variations and embodiments are also possible. Closed loopperformance controller 1901 implements a scalability model 1902 todetermine a CPU control effort parameter (CPU-CE), while using aproportional-integral (PI) controller 1903 to determine a GPU controleffort parameter (GPU-CE). In some embodiments a scalability model couldbe used to set the GPU control effort, or to set control effortsassociated with other processing elements, such as neural engines orother specialized processors as discussed above. At a high level, CLPC1901 operates similarly to the CLPCs described above. More specifically,a work interval state machine 1904 may receive inputs including I/Operformance control inputs related to other components 1904 of thesystem (i.e., meta data relating to the timing and control of datainputs and outputs for the processor complex). Additionally, workinterval state machine 1903 receives inputs relating to workload(s) 1905that provide information about the required performance, timing,deadlines, etc. for each thread group. This data may be delivered toCLPC 1901 and work interval state machine 1903 via the APIs discussedabove.

From the received data, work interval state machine 1903 can determine,for each thread group, critical time and total time spent by eachprocessing agent on a given thread group. For example, work intervalstate machine 1903 may determine, for each thread group, critical andtotal time on a CPU, a GPU, a neural engine, and/or other processingelements. Additionally, work interval state machine 1903 can determinean error in meeting a deadline for each thread group. All of thisinformation, i.e., critical time and total time for each processingagent on a given thread group and error in meeting the thread groupdeadline, may be provided to error distribution logic 1906. Errordistribution logic 1906 may operate according to various combinations ofthe principles discussed above with respect to FIGS. 16A-18B to allocatethe error in meeting a deadline for a thread group among the processingagents associated with that thread group. Thus, error distribution logic1906 may also receive inputs from outside CLPC 1901 that provideinformation relating to processing agent power estimates and tuningparameters (as discussed above).

Error Distribution Logic

Turning back to FIG. 15B, discussed above, provides context for anexplanation of how error distribution logic may operate. As discussedabove, the critical path may dictate how the various processing agentsmay have their performance adjusted, because reduction of criticalexecution time of a processing agent provides a 1:1 reduction in thetotal execution time of the thread group. In the foregoing examples, forexample, those discussed with respect to FIGS. 17A, 17B, and 18B,isolated execution is used as a proxy for criticality. Isolatedexecution time is, by definition, critical execution time; however,there may be a portion of shared execution time 1525 that is alsocritical with respect to one of a plurality of processing agentsoperating during that time. Nonetheless, for purposes of the controltechniques discussed herein, isolated execution time achieves thedesired objectives without the added difficulty and complexity ofdetermining a critical agent during a shared execution time.

In addition to criticality of a given processing agent, the degree ofserialization of a workload, which may be determined as set forth above,may also inform performance control of the various processing agents ina system. For a more serialized workload, it may be preferable to adjustthe performance of the processing agents based on their relativecritical time. In other words, with a highly serialized load, for amissed deadline, the largest benefits may come from increasingperformance of the processing agent with the longest critical time.Conversely, for a deadline met too far in advance, indicatingunnecessary power expenditure, decreasing the performance of theprocessing agent with the shortest critical time may provide thegreatest benefits. The techniques were as illustrated in and discussedwith respect to FIG. 17A. Conversely, for a less serialized/morepipelined load, the greatest performance benefits may be achieved byproportionally adjusting the performance of each processing agentaccording to its fraction of the critical time as illustrated in anddiscussed with respect to FIG. 17B.

Finally, taking into account power efficiency, it may be desirable toavoid increasing the performance of processing agents that are alreadyconsuming too much power. Conversely, it may also be generally desirableto decrease the performance of processing agents consuming the mostpower, where possible.

Thus, with continued reference to FIG. 19, error distribution logic 1906may take as inputs a start time of a workload associated with a threadgroup, a finish time of the workload associated with a thread group, adeadline for completing the workload thread group. Error distributionlogic 1906 may also take as inputs, for each processing agent, acritical processing time, a total processing time, and a powerconsumption. These inputs may be processed as follows to determineappropriate control efforts for each processing agent. Morespecifically, a utilization measure for the processor complex as a wholemay be given by:

${utilization} = \frac{T_{{fini}sh} - T_{start}}{T_{deadline} - T_{start}}$where utilization is the utilization measure for the processor complex,T_(finish) is the finish time of processing on the processor complex,T_(start) is the start time of processing on the processor complex, andT_(deadline) is the deadline time. A utilization error for the processorcomplex as a whole may thus be given by:error_util=utilization−target_utilizationwhere error_util is the utilization error for the processor complex,utilization is the utilization measure for the processor complex, andtarget_utilization is the target utilization for the processor complex.The degree of serialization of the workload may thus be determined by

${DoS} = \frac{\sum T_{{critical}_{i}}}{T_{{fini}sh} - T_{start}}$where DoS is the degree of serialization, Tcritical_(i) is the criticaltime for each processing agent i, and T_(finish) and T_(start) are thefinish and start times of the workload on the processor complex,respectively. An allocated error component for each processing agent canthus be given by:error_util_(i)=(1−DoS+DoS−ϕ_(i))·error_utilwhere error_util_(i) is the allocated error for a given processing agenti, DoS is the degree of serialization, ϕ_(i) is an efficiency measurecomputed as described below.

Efficiency measure ϕ_(i) may be computed by two different formulas, onebeing the reciprocal of the other. For cases where the utilization erroris positive (i.e., a deadline has been issued), ϕ_(i) may be given by:

$\phi_{i} = \frac{\frac{{Tcri}t_{i}}{P_{i}}}{\sum\frac{{Tcri}t_{i}}{P_{i}}}$where ϕ_(i) is a measure of the efficiency of an agent i; Tcrit_(i) isthe critical time of agent i on the work interval; ΣTc_(i) is the totalcritical utilization of the work interval; and P_(i) the power consumedby the agent. For cases where the utilization error is negative (i.e., adeadline has been met too early), ϕ_(i) may be given by:

$\phi_{i} = \frac{\frac{P_{i}}{{Tcri}t_{i}}}{\sum\frac{P_{i}}{{Tcri}t_{i}}}$where ϕ_(i) is a measure of the efficiency of an agent i; Tcrit_(i) isthe critical time of agent i on the work interval; ΣTc_(i) is the totalcritical utilization of the work interval; and P_(i) the power consumedby the agent.

Returning to FIG. 19, the allocated error for the CPU (which may becomputed in accordance with the formulas above) may be input intoscalability model 1902. As described above, scalability model may thusincrease or decrease the CPU control effort contribution (CPU_CE) inproportion to the allocated CPU error. As these parameters are computedon a per thread group basis, the maximum computed control effortcontribution, corresponding to the thread group requiring the mostcomputational resources, may be used to set the performance state of theCPU. Additionally, the allocated error for the GPU (which may becomputed in accordance with the formulas above) may be input into PIcontroller 1903, which may thus increase or decrease the GPU controleffort contribution (GPU_CE) associated with the thread group inresponse to the allocated GPU error. Again, as these parameters arecomputed on a per thread group basis, the maximum computed controleffort contribution, corresponding to the thread group requiring themost computational resources, may be used to set the performance stateof the GPU.

Error Distribution Special Cases

The foregoing mathematical treatment of the error distribution logiccaptures a variety of nominal operating conditions for the processorcomplex. However, there may be certain edge cases in which it isnecessary to modify the error distribution logic to obtain suitableperformance. For example, in the case where the performance of an agentis already at its maximum, but a deadline is not being met, it is notpossible to further increase the performance of that agent to take itsallocated share of the utilization error. Similarly, in the case wherethe performance of an agent is already at its minimum, but deadlines arestill being met too soon, implying inefficient power use, it is notpossible to further decrease the performance of that agent to take itsallocated share of the utilization error. Thus, in such cases, it mightbe preferable to provide a mechanism that (1) determines whether therequested performance change for an agent is possible given the currentperformance state of the agent and (2) reallocate that agent'sproportional share of the error to other agents that still haveadjustment headroom.

Another edge case exists at the beginning stage of a multi-agentworkload. In one example, a CPU may have just started executing, andwill thus have a non-zero power consumption value. However, a GPU maynot be running yet, and will thus have a zero power consumption value.As a result, the algorithm described above may disproportionatelyallocate increased performance to the GPU. However, because GPUs are, ingeneral, less power efficient than CPUs, this may result ininefficiency. Thus, it may be desirable to provide a bias factor thatpreferentially allocates error to a more power efficient component, orless preferentially allocates error to a less power efficient component.Additionally, one could ensure that the error distribution logic alwayssees a minimum floor for the less power efficient component, to avoidover allocation of error to the less power efficient component.

Any of the foregoing deadline driven control algorithms may be enhancedin a variety of other ways. For example, heuristics could beincorporated into the various algorithms. These heuristics could beselected and or tuned to achieve a desired result in a particularembodiment. For example, one such heuristic could be speeding up oneprocessing element (e.g., a processor or CPU) the before speeding upcoprocessors (e.g., a GPU or neural engine). The reverse mightalternatively be desirable in some applications. Additionally oralternatively, the performance adjustment of a particular agent might bebiased so that that element receives more or less adjustment, dependingon how effective performance increases are with respect to that agent orwith respect to a particular workload.

Some embodiments described herein can include one or more applicationprogramming interfaces (APIs) in an environment with calling programcode interacting with other program code being called through the one ormore interfaces. Various function calls, messages, or other types ofinvocations, which further may include various kinds of parameters, canbe transferred via the APIs between the calling program and the codebeing called. In addition, an API may provide the calling program codethe ability to use data types or classes defined in the API andimplemented in the called program code.

In the foregoing specification, the invention has been described withreference to specific embodiments thereof. It will, however, be evidentthat various modifications and changes can be made thereto withoutdeparting from the broader spirit and scope of the invention. Thespecification and drawings are, accordingly, to be regarded in anillustrative rather than a restrictive sense.

In the foregoing specification, the invention has been described withreference to specific embodiments thereof. It will, however, be evidentthat various modifications and changes can be made thereto withoutdeparting from the broader spirit and scope of the invention. Thespecification and drawings are, accordingly, to be regarded in anillustrative rather than a restrictive sense.

The invention claimed is:
 1. A method of controlling performance of oneor more processors or coprocessors of an asymmetric multiprocessorsystem, the method comprising: executing a thread group on a processorand a coprocessor of the asymmetric multiprocessor system, wherein thethread group has a first control effort parameter corresponding to theprocessor and a second control effort parameter corresponding to thecoprocessor; storing a value of the first control effort parameter whena workload is submitted to the coprocessor; and resetting the firstcontrol effort parameter to a value derived from the stored value of thefirst control effort parameter when a result of the workload isdelivered to the processor.
 2. The method of claim 1 wherein resettingthe first control effort parameter to the derived value includesresetting the first control effort parameter to the stored value of thefirst control effort parameter.
 3. The method of claim 1 whereinresetting the first control effort parameter to the derived valueincludes resetting the first control effort parameter to the storedvalue of the first control effort parameter times a factor derived fromthe degree of serialization of the workload.
 4. The method of claim 1wherein resetting the first control effort parameter to the derivedvalue includes resetting the first control effort parameter to thestored value of the first control effort parameter times a factorderived from a length of time required to execute the workload.
 5. Themethod of claim 1 wherein resetting the first control effort parameterto the derived value includes resetting the first control effortparameter to the stored value of the first control effort parametertimes a tuning factor.
 6. The method of claim 5 wherein the tuningfactor is derived from a performance priority of the workload.
 7. Themethod of claim 5 wherein the tuning factor is derived from a desiredlevel of power consumption for the workload.
 8. The method of claim 1wherein the processor is selected from the group consisting of a centralprocessing unit, a graphics processing unit, a general purpose graphicsprocessing unit, a neural engine, an image signal processor, and ascaling and rotating engine.
 9. The method of claim 1 wherein thecoprocessor is selected from the group consisting of a centralprocessing unit, a graphics processing unit, a general purpose graphicsprocessing unit, a neural engine, an image signal processor, and ascaling and rotating engine.
 10. The method of claim 1 wherein thecontrol effort parameter affects at least one of an allocated subset ofcores or execution units and a dynamic voltage and frequency state ofthe processor.
 11. An asymmetric multiprocessor system comprising: aprocessor complex comprising one or more processors; one or morecoprocessors; a closed loop performance controller configured to controlperformance of the one or more processors and the one or morecoprocessors; and an operating system executing on the processorcomplex, the operating system comprising an input/output serviceinteractive with the closed loop performance controller and one or moredrivers corresponding to the one or more coprocessors; wherein theclosed loop performance controller is configured to cooperate with theoperating system, the processor complex, and the one or morecoprocessors to: execute a thread group on a processor and a coprocessorof the asymmetric multiprocessor system, wherein the thread group has afirst control effort parameter corresponding to the processor and asecond control effort parameter corresponding to the coprocessor; storea value of the first control effort parameter when a workload issubmitted to the coprocessor; and reset the first control effortparameter to a value derived from the stored value of the first controleffort parameter when a result of the workload is delivered to theprocessor.
 12. The asymmetric multiprocessor system of claim 11 whereinthe closed loop performance controller resets the first control effortparameter to the derived value by resetting the first control effortparameter to the stored value of the first control effort parameter. 13.The asymmetric multiprocessor system of claim 11 wherein the closed loopperformance controller resets the first control effort parameter to thederived value by resetting the first control effort parameter to thestored value of the first control effort parameter times a factorderived from the degree of serialization of the workload.
 14. Theasymmetric multiprocessor system of claim 11 wherein the closed loopperformance controller resets the first control effort parameter to thederived value by resetting the first control effort parameter to thestored value of the first control effort parameter times a factorderived from a length of time required to execute the workload.
 15. Theasymmetric multiprocessor system of claim 11 wherein the closed loopperformance controller resets the first control effort parameter to thederived value by resetting the first control effort parameter to thestored value of the first control effort parameter times a tuningfactor.
 16. The asymmetric multiprocessor system of claim 15 wherein thetuning factor is derived from a performance priority of the workload.17. The asymmetric multiprocessor system of claim 15 wherein the tuningfactor is derived from a desired level of power consumption for theworkload.
 18. The asymmetric multiprocessor system of claim 11 whereinthe processor is selected from the group consisting of a centralprocessing unit, a graphics processing unit, a general purpose graphicsprocessing unit, a neural engine, an image signal processor, and ascaling and rotating engine.
 19. The asymmetric multiprocessor system ofclaim 11 wherein the coprocessor is selected from the group consistingof a central processing unit, a graphics processing unit, a generalpurpose graphics processing unit, a neural engine, an image signalprocessor, and a scaling and rotating engine.
 20. The asymmetricmultiprocessor system of claim 11 wherein the first control effortparameter affects at least one of an allocated subset of cores orexecution units and a dynamic voltage and frequency state of theprocessor.